Section 90

EurekaMag Full Text Articles Chapter 89,009


Kubota, Y.; Kodaira, J.; Miyahara, A. 1980: Thermal interlock system with quick response time for high‐power magnetic coil systems. Review of Scientific Instruments 51(12): 1722-1723
Druliner, J.D. 1968: Thermal intermolecular exchange between N-acylbenzotriazoles. Journal of the American Chemical Society 90(24): 6879-6880
Purcell, K.F.; Hoff, C.D.; Vrtiska, T.J. 1983: Thermal intersystem crossing in solids. Cophen2(NCBR3)2, R = H and phenyl. Inorganica Chimica Acta 76: L23-L24
Bertram, H.; Wieghardt, K. 1979: Thermal intramolecular cobalt(III)-iron(II) and cobalt(III)-titanium(III) electron-transfer reactions involving outer-sphere and inner-sphere precursor complexes. Inorganic Chemistry 18(7): 1799-1807
Kitano, H.; Fujita, S.; Takehara, Y.; Hattori, M.; Morita, T.; Matsumoto, K.; Hatanaka, M. 2003: Thermal intramolecular cycloaddition of 4-alkenylfulve≠ highly regio- and diastereoselective formation of [4+2] adduct. Tetrahedron 59(15): 2673-2677
Egger, K.W. 1968: Thermal intramolecular rearrangement of methyl-1,3,5-cycloheptatrienes in the gas phase. II. Thermodynamic data from equilibrium studies of the positional isomers. Journal of the American Chemical Society 90(1): 1-5
Egger, K.W. 1968: Thermal intramolecular rearrangement of methyl-1,3,5-cycloheptatrienes in the gas phase. III. Kinetic data for the unimolecular skeletal rearrangement into benzene derivatives and the equilibrium between 1,3,5-cycloheptatriene and bicyclo-[4.1.0]hepta-2,4-diene. Journal of the American Chemical Society 90(1): 6-11
Liu, W.; Ge, X.; Zhou, X.; Tang, Y. 2015: Thermal intumescent behavior of a gel containing silica. RSC Advances 5(42): 33208-33211
Watson, I.; Gentilli, J. 1974: Thermal inversion by advection in a subtropical summer. Australian Geographical Studies 12(1): 119-125
Shen, J.; Naldi, G.; Pomfret, D.; Wheeler, C. 2020: Thermal investigation and optimised design of a ship loader. Powder Technology 374: 201-213
Huang, X.; Li, Y.; Ke, T.; Ling, X.; Liu, W. 2017: Thermal investigation and performance analysis of a novel evaporation system based on a humidification-dehumidification process. Energy Conversion and Management 147: 108-119
Mohammadian, E.; Ghasemi, S.; Poorgashti, H.; Hosseini, M.; Ganji, D. 2014: Thermal investigation of Cu–water nanofluid between two vertical planes. Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering 229(1): 36-43
Rahgoshay, S.; Ranjbar, A.; Ramiar, A.; Alizadeh, E. 2017: Thermal investigation of a PEM fuel cell with cooling flow field. Energy 134: 61-73
Palanikumar, G.; Shanmugan, S.; Chithambaram, V.; Gorjian, S.; Pruncu, C.I.; Essa, F.; Kabeel, A.; Panchal, H.; Janarthanan, B.; Ebadi, H.; Elsheikh, A.H.; Selvaraju, P. 2021: Thermal investigation of a solar box-type cooker with nanocomposite phase change materials using flexible thermography. Renewable Energy 178: 260-282
Tomić, Z.P.; Kaluđerović, L.; Nikolić, N.; Marković, S.; Makreski, P. 2015: Thermal investigation of acetochlor adsorption on inorganic- and organic-modified montmorillonite. Journal of Thermal Analysis and Calorimetry 123(3): 2313-2319
Dröske, N.C.; Förster, F.J.; Weigand, B.; von Wolfersdorf, J. 2017: Thermal investigation of an internally cooled strut injector for scramjet application at moderate and hot gas conditions. Acta Astronautica 132: 177-191
Mitra, S.; De, G.; Chaudhuri, N. 1983: Thermal investigation of diamine complexes of nickel(II) in the solid phase. Thermochimica Acta 66(1-3): 187-195
Sowmya, G.; B.J., G.; Khan, M.I.; Momani, S.; Hayat, T. 2020: Thermal investigation of fully wet longitudinal porous fin of functionally graded material. International Journal of Numerical Methods for Heat-Fluid Flow 30(12): 5087-5101
Mothé, M.G.; Mothé, C.G.; de Carvalho, C.H.M.; de Oliveira, M.C.K. 2013: Thermal investigation of heavy crude oil by simultaneous TG–DSC–FTIR and EDXRF. Journal of Thermal Analysis and Calorimetry 113(2): 525-531
Cui, P.; Diao, N.; Gao, C.; Fang, Z. 2015: Thermal investigation of in-series vertical ground heat exchangers for industrial waste heat storage. Geothermics 57: 205-212
Teresa Caccamo, M.; Mavilia, G.; Mavilia, L.; Calandra, P.; Lombardo, D.; Magazù, S.; , 2020: Thermal investigation of montmorillonite/BSA by fourier transform infrared spectroscopy measurements1. AIMS Biophysics 7(4): 436-451
Hassab, M.A.; Mansour, M.K.; Sorour, M.M.M. 2017: Thermal investigation of the conjugate heat transfer problem in multi-row circular minichannels. Numerical Heat Transfer, Part A: Applications 71(12): 1205-1222
Liptay, G.; Sors, L. 1976: Thermal investigation of the manufacture of active substance for lead storage batteries. Thermochimica Acta 14(3): 279-297
Shuttleworth, P.S.; Budarin, V.; Clark, J.H. 2010: Thermal investigation of 'molten starch'. Journal of Thermal Analysis and Calorimetry 105(2): 577-581
Abdel-Fattah, W.I.; El-Didamony, H. 1981: Thermal investigation on electrostatic precipitator kiln dust. Thermochimica Acta 51(2-3): 297-306
Medina, D.A.V.; Ferreira, A.P.G.; Cavalheiro, E.T.G. 2014: Thermal investigation on polymorphism in sodium saccharine. Journal of Thermal Analysis and Calorimetry 117(1): 361-367
Courtois, B.; Székely, V.; Rencz, M. 1998: Thermal investigations of ICs and microstructures. Sensors and Actuators A: Physical 71(1-2): 1-2
Wers, E.; Oudadesse, H.; Lefeuvre, B.; Bureau, B.; Merdrignac-Conanec, O. 2014: Thermal investigations of Ti and Ag-doped bioactive glasses. Thermochimica Acta 580: 79-84
Urbaniak, M.; Grudzinski, K. 2004: Thermal investigations of curing process of EPY epoxy system. Polimery 49(02): 89-93
Kettwich, S.C.; Kappagantula, K.; Kusel, B.S.; Avjian, E.K.; Danielson, S.T.; Miller, H.A.; Pantoya, M.L.; Iacono, S.T. 2014: Thermal investigations of nanoaluminum/perfluoropolyether core–shell impregnated composites for structural energetics. Thermochimica Acta 591: 45-50
Rajić, N.; Gabrovšek, R.; Ristić, A.; Kaučič, V. 1997: Thermal investigations of some Al PO and me APO materials prepared in the presence of HF. Thermochimica Acta 306(1-2): 31-36
Vladut, C.M.; Mihaiu, S.; Szilágyi, I.M.; Kovács, T.N.; Atkinson, I.; Mocioiu, O.C.; Petrescu, S.; Zaharescu, M. 2018: Thermal investigations of the Sn–Zn–O gels obtained by sol–gel method. Journal of Thermal Analysis and Calorimetry 136(2): 461-470
Banerjee, B.; Biswas, P.; Chaudhuri, N. 1981: Thermal investiongation of metal fluoberyllate hydrates and metal fluoride hydrates. Thermochimica Acta 47(2): 179-188
Lissi, E.; Sanhueza, E. 1971: Thermal iodination of triethylborane. Journal of Organometallic Chemistry 32(3): 285-290
Sasaki, N.; Kubo, K.; Asano, M. 1974: Thermal ion emission from some transition metal carbides heated on graphite filament. The Journal of Chemical Physics 60(4): 1575-1577
Lockwood, M. 1982: Thermal ion flows in the topside auroral ionosphere and the effects of low-altitude, transverse acceleration. Planetary and Space Science 30(6): 595-609
Knudsen, D.J.; Burchill, J.K.; Buchert, S.C.; Eriksson, A.I.; Gill, R.; Wahlund, J.; Åhlen, L.; Smith, M.; Moffat, B. 2017: Thermal ion imagers and Langmuir probes in the Swarm electric field instruments. Journal of Geophysical Research: Space Physics 122(2): 2655-2673
Grebowsky, J.; Taylor Jr., H.; Pharo Iii, M.; Reese, N. 1987: Thermal ion perturbations observed in the vicinity of the Space Shuttle. Planetary and Space Science 35(4): 501-513
Brinton, H.; Pickett, R.; Taylor Jr., H. 1968: Thermal ion structure of the plasmasphere. Planetary and Space Science 16(7): 899-909
Kumakura, M.; Sugiura, T. 1978: Thermal ion-molecule reactions in oxygen-containing molecules. Condensation-elimination and addition reactions in simple aliphatic ketones. The Journal of Physical Chemistry 82(6): 639-643
Aggarwal, S.K. 2016: Thermal ionisation mass spectrometry (TIMS) in nuclear science and technology – a review. Analytical Methods 8(5): 942-957
Torchynska, T.; Casas Espinola, J.; Velásquez Losada, E.; Eliseev, P.; Stintz, A.; Malloy, K.; Pena Sierra, R. 2003: Thermal ionisation of ground and multiply excited states in in as quantum dots embedded into in Ga As/Ga as MQW. Surface Science 532-535: 848-851
Katsuragawa, M.; Sota, S.; Komori, M.; Anbe, C.; Takeuchi, T.; Sakai, H.; Amano, H.; Akasaki, I. 1998: Thermal ionization energy of Si and Mg in Al Ga N. Journal of Crystal Growth 189-190: 528-531
Crouch, R.K.; Gilmer Jr., T. 1969: Thermal ionization energy of lithium and lithium-oxygen complexes in single-crystal silicon. Journal of Physics and Chemistry of Solids 30(8): 2037-2043
Wieser, M.E.; De Laeter, J.R. 2000: Thermal ionization mass spectrometry of molybdenum isotopes. International Journal of Mass Spectrometry 197(1-3): 253-261
Rokop, D.J.; Perrin, R.E.; Knobeloch, G.W.; Armijo, V.M.; Shields, W.R. 1982: Thermal ionization mass spectrometry of uranium with electrodeposition as a loading technique. Analytical Chemistry 54(6): 957-960
Glukhov, I.; Ovsiannikov, V. 2009: Thermal ionization of Cs Rydberg states. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 267(2): 310-312
Yau, L.D.; Sah, C.T. 1971: Thermal ionization rates and energies of electrons and holes at silver centers in silicon. Physica Status Solidi (a) 6(2): 561-573
Herman, J.M.; Sah, C.T. 1972: Thermal ionization rates and energies of holes at the double acceptor zinc centers in silicon. Physica Status Solidi (a) 14(2): 405-415
Kumakura, M.; Arakawa, K.; Sugiura, T. 1978: Thermal ion–molecule reactions in oxygen‐containing molecules. Formation of long‐lived intermediate ions in acetyl chloride. The Journal of Chemical Physics 69(11): 5082-5087
Mitchell, D.G.; Roelof, E.C.; Feldman, W.C.; Bame, S.J.; Williams, D.J. 1981: Thermal iron ions in high speed solar wind streams, 2. Temperatures and bulk velocities. Geophysical Research Letters 8(7): 827-830
Garde, C S.; Ray, J. 1994: Thermal irreversibility effects close to the antiferromagnetic transition temperature in Pr(Cu1-x Nix)2Si2systems. Journal of Physics: Condensed Matter 6(44): L671-L675
Binici, H.; Aksogan, O.; Bodur, M.N.; Akca, E.; Kapur, S. 2007: Thermal isolation and mechanical properties of fibre reinforced mud bricks as wall materials. Construction and Building Materials 21(4): 901-906
Boateng, E.; Schubel, P.; Umer, R. 2019: Thermal isolation of FBG optical fibre sensors for composite cure monitoring. Sensors and Actuators A: Physical 287: 158-167
Kessler, H. 1974: Thermal isomerization about double bonds. Tetrahedron 30(13): 1861-1870
Lifshitz, A.; Tamburu, C.; Dubnikova, F. 2007: Thermal isomerization and cyclization of 1-naphthylacetylene: Experimental results, quantum chemical and transition state theory calculations. Proceedings of the Combustion Institute 31(1): 241-248
Gusel'nikov, L.; Sokolova, V.; Volnina, E.; Zaikin, V.; Nametkin, N.; Voronkov, M.; Kirpichenko, S.; Keiko, V. 1981: Thermal isomerization and decomposition of 3,3-diethyl-2,4-dimethyl-3-silathietane. Journal of Organometallic Chemistry 214(2): 145-154
Bernier, P.; Lefrant, S.; Rolland, M.; Aldissi, M.; Galtier, M.; Montaner, A.; Linaya, C.; Schue, F. 1983: Thermal isomerization and degradation of polyacetylene. Journal of Electronic Materials 12(2): 289-322
Dolbier Jr., W.R.; Enoch, H.O. 1977: Thermal isomerization and fragmentation of 1,1-difluoro-2,3-dimethylcyclopropane. Journal of the American Chemical Society 99(13): 4532-4533
Minor, S.S.; Everett, G.W. 1976: Thermal isomerization and photoisomerization of a chiral chromium(III)-.beta.-diketone complex in n-hexane solution. Inorganic Chemistry 15(7): 1526-1530
Taylor, P.M.; Fuller, G. 1969: Thermal isomerization equilibrium between conjugated and unconjugated unsaturated keto-esters. The Journal of Organic Chemistry 34(11): 3627-3630
Ashman, C.; Khanna, S.N.; Pederson, M.R.; Porezag, D.V. 1998: Thermal isomerization in Cs4Cl3−. Physical Review A 58(1): 744-747
Marković, S.; Stanković, S.; Radenković, S.; Gutman, I. 2008: Thermal isomerization in cyclopenta aceanthrylene. Monatshefte für Chemie - Chemical Monthly 140(2): 153-156
Fatemi, F.K.; Fatemi, D.J.; Bloomfield, L.A. 1999: Thermal isomerization in isolated cesium–halide cluster anions. The Journal of Chemical Physics 110(11): 5100-5108
Pincock, R.E.; Wilson, K.R.; Kiovsky, T.E. 1967: Thermal isomerization in polycrystalline exo- and endo-5-norbornene-2,3-dicarboxylic anhydrides. Journal of the American Chemical Society 89(26): 6890-6897
Andrews, G.D.; Baldwin, J.E. 1976: Thermal isomerization of (+)-(1S,2S)-trans,trans-2-methyl-1-propenylcyclopropane: quantification of four stereochemical paths in a vinylcyclopropane rearrangement. Journal of the American Chemical Society 98(21): 6705-6706
Baldwin, J.E.; Gilbert, K.E. 1976: Thermal isomerization of (-)-(1R,5R)-6-exo-vinylbicyclo[3.1.0]hex-2-ene to (-)-(1R,5R)-bicyclo[3.2.1]octa-2,6-diene: one-center thermal epimerization of a cyclopropane. Journal of the American Chemical Society 98(25): 8283-8284
Murakami, K.; Honda, M.; Wahyudiono; Kanda, H.; Goto, M. 2017: Thermal isomerization of (all-E)-lycopene and separation of the Z-isomers by using a low boiling solvent: Dimethyl ether. Separation Science and Technology 52(16): 2573-2582
Schiess, P.; Dinkel, R. 1975: Thermal isomerization of 1,1-disubstituted cyclohexa-2,4-dienes. Tetrahedron Letters 16(29): 2503-2506
Baldwin, J.E.; Andrist, A.H. 1971: Thermal isomerization of 1,2,7,8,9,9-hexadeuterio-cis-bicyclo[6.1.0]nona-2,4,6-triene. Journal of the American Chemical Society 93(16): 4055-4056
Ohshita, J.; Takayama, H.; Ishikawa, M.; Kunai, A. 2003: Thermal isomerization of 1,2-diadamantoyltetrakis(trimethylsilyl)disilane via a 2,3-disilabutadiene intermediate. Journal of Organometallic Chemistry 672(1-2): 72-76
Baldwin, J.E.; Ullenius, C. 1974: Thermal isomerization of 1,2-dialkenylcyclopropanes. Journal of the American Chemical Society 96(5): 1542-1547
Dolbier Jr., W.R.; Fielder Jr., T.H. 1978: Thermal isomerization of 2,2-difluoromethylenecyclopropane. Journal of the American Chemical Society 100(17): 5577-5578
Kostikov, R.R.; Khlebnikov, A.F.; Ogloblin, K.A. 1978: Thermal isomerization of 3,3-dihalo-1,2-diphenylaziridines. Chemistry of Heterocyclic Compounds 14(1): 37-41
Baldwin, J.E.; Andrist, A.H.; Pinschmidt Jr., R.K. 1972: Thermal isomerization of 3,6-dideuterio- and 1,2,7,8,9,9-hexadeuterio-cis-bicyclo[6.1.0]nona-2,4,5-triene. Journal of the American Chemical Society 94(16): 5845-5851
Tada, M.; Takahashi, T. 1973: Thermal isomerization of 3-acylfuran to its isomeric 3-acylfuran. Thermal interconversion between ligularone and isoligularone. Tetrahedron Letters 14(41): 3999-4002
Brown, H.C.; Racherla, U.S. 1982: Thermal isomerization of 3-hexyldicycloalkylboranes: evidence for an important steric factor on the rate of isomerization and equilibrium distribution. Organometallics 1(5): 765-766
Grosclaude, J.P.; Gonzenbach, H.U.; Perlberger, J.C.; Schaffner, K. 1975: Thermal isomerization of 5-acetyl-5-methylbicyclo[2.1.0]pentane. Endo-exo stereomutation and cyclopropyl-allylic rearrangement of the endo ketone on separate potential energy surfaces. Journal of the American Chemical Society 97(14): 4147-4148
Komendantov, M.I.; Bekmukhametov, R.R.; Kostikov, R.R. 1978: Thermal isomerization of 5-methoxy-3-arylisoxazoles to methyl 3-aryl-2H-azirine-2-carboxylates. Chemistry of Heterocyclic Compounds 14(8): 843-846
Andrews, G.D.; Baldwin, J.E. 1977: Thermal isomerization of 5-methylbicyclo[2.1.0]pent-2-enes and [1,5-13C2]bicyclo[2.1.0]pent-2-ene. Journal of the American Chemical Society 99(14): 4853-4854
Toy, M.S.; Stringham, R.S. 1979: Thermal isomerization of a perfluorobicyclo[2.2.0]hexene derivative. Journal of Fluorine Chemistry 13(5): 463-464
Takeda, H.; Schuller, W.H.; Lawrence, R.V. 1968: Thermal isomerization of abietic acid. The Journal of Organic Chemistry 33(4): 1683-1684
Padwa, A.; Blacklock, T.J. 1980: Thermal isomerization of allyl-substituted cyclopropenes. An example of a nonsynchronous cope rearrangement. Journal of the American Chemical Society 102(8): 2797-2806
Andrist, A.H.; Slivon, L.E.; Graas, J.E. 1978: Thermal isomerization of allylic alcohols to saturated ketones. The Journal of Organic Chemistry 43(4): 634-637
Jones Jr., M.; Fairless, B. 1968: Thermal isomerization of bicyclo[4.2.2]deca-2,4,7,9-tetraene. Tetrahedron Letters 9(47): 4881-4884
Hancock, K.G.; Kramer, J.D. 1973: Thermal isomerization of but-1-en-3-yl(dimethylamino)ethylborane. Reluctant 1,3-sigmatropic shift of boron in an unusually stable allylborane. Journal of the American Chemical Society 95(19): 6463-6465
Dauben, W.G.; Michno, D.M.; Olsen, E.G. 1981: Thermal isomerization of cyclic cis, trans, cis-trienes. The Journal of Organic Chemistry 46(4): 687-690
Sakurai, H.; Hosomi, A.; Kumada, M. 1968: Thermal isomerization of cyclopropyl-substituted silanes. Tetrahedron Letters 9(20): 2469-2470
Ferrar, L.; Mis, M.; Robello, D.R. 2008: Thermal isomerization of dewarbenzene derivatives. Tetrahedron Letters 49(26): 4130-4133
Kwie, W.W.; Gardiner Jr., W. 1963: Thermal isomerization of dimethyl maleate. Tetrahedron Letters 4(6): 405-408
Belsky, I.; Dodiuk, H.; Shvo, Y. 1977: Thermal isomerization of heterofulvenes. Dynamic nuclear magnetic resonance study. The Journal of Organic Chemistry 42(16): 2734-2741
Haller, I. 1968: Thermal isomerization of hexafluorobicyclo[2.2.0]hexa-2,5-diene. The Journal of Physical Chemistry 72(8): 2882-2885
Ewing, G.D.; Ley, S.V.; Paquette, L.A. 1978: Thermal isomerization of homoazocines. Journal of the American Chemical Society 100(9): 2909-2911
Subramanyam, R.; Bartlett, P.D.; Iglesias, G.Y.M.; Watson, W.H.; Galloy, J. 1982: Thermal isomerization of isodicyclopentadiene and its cycloaddition reactions. The Journal of Organic Chemistry 47(23): 4491-4498
Takeda, H.; Schuller, W.H.; Lawrence, R.V. 1968: Thermal isomerization of methyl abietate. Journal of Chemical-Engineering Data 13(4): 579-581
Toy, M.S.; Stringham, R.S. 1979: Thermal isomerization of perfluorobicyclo[2.2.0]hexene oxides. The Journal of Organic Chemistry 44(15): 2813-2814
Lai, H.; Chen, K.; Li, Y.; Wu, C.; Hu, C.; Lin, C.; Huang, J. 2019: Thermal isomerization of ruthenium hydride compounds containing asymmetric bidentate pyrrole‐imine ligands. Journal of the Chinese Chemical Society 66(9): 1041-1047
Patterson, J.M.; Soedigdo, S. 1968: Thermal isomerization of some trisubstituted pyrroles. The Journal of Organic Chemistry 33(5): 2057-2061
Patterson, J.M.; De Haan, J.W.; Boyd, M.R.; Ferry, J.D. 1972: Thermal isomerization of substituted allylpyrroles. Journal of the American Chemical Society 94(7): 2487-2494
Zhigulev, K.K.; Khmel'nitskii, R.A.; Panina, M.A. 1974: Thermal isomerization of the isoxazole ring and rearrangement processes in the mass spectra of 3-aryl-5-methylisoxazole-4-carboxylic acids. Chemistry of Heterocyclic Compounds 10(4): 397-399
Hisatsune, I.C.; Passerini, R.; Pichai, R.; Schettino, V. 1969: Thermal isomerization of the maleate ion in potassium halide matrixes. The Journal of Physical Chemistry 73(11): 3690-3692
Zompatori, A.; Tortelli, V. 2004: Thermal isomerization of trifluoromethyl trifluorovinyl ether to pentafluoropropionyl fluoride. Journal of Fluorine Chemistry 125(2): 199-204
Paquette, L.A.; Carmody, M.J. 1975: Thermal isomerization reactions of cis-9,10-dihydronaphthalene derivatives. Journal of the American Chemical Society 97(20): 5841-5850
Miller, V.R.; Grimes, R.N. 1975: Thermal isomerization studies of small metallocarboranes. Cage rearrangement equilibriums and reversible cobalt atom migrations. Journal of the American Chemical Society 97(15): 4213-4220
Laguitton, B.; Mison, P.; Pascal, T.; Sillion, B. 1995: Thermal isomerization studies of the two lowest molecular weight components of a nadimide end-capped thermoset. Polymer Bulletin 34(4): 425-432
Hopf, H.; Priebe, H.; Walsh, R. 1980: Thermal isomerization. 9. the role of cyclopropene in the allene to propyne isomerization. a study of the thermal rearrangements of C3H3D isomers. Journal of the American Chemical Society 102(3): 1210-1212
Lustgarten, R.K.; Richey Jr., H.G. 1974: Thermal isomerizations of 7-alkoxy- and 7-phenylbicyclo[2.2.1]heptadienes to cycloheptatrienes. Journal of the American Chemical Society 96(20): 6393-6402
Leber, P.A.; Bogdan, A.R.; Powers, D.C.; Baldwin, J.E. 2007: Thermal isomerizations of cis,anti,cis-tricyclo[,7]dodec-3-ene to trans- and cis,endo-tricyclo[,7]dodec-9-ene: diradical conformations and stereochemical outcomes in [1,3] carbon shifts. Tetrahedron 63(27): 6331-6338
Dolbier Jr., W.R.; Sellers, S.F. 1982: Thermal isomerizations of cis- and trans-2,2-difluoro-3-methyl-1-vinylcyclopropane. The Journal of Organic Chemistry 47(1): 1-4
Dalrymple, D.L.; Russo, W.B. 1975: Thermal isomerizations of dimethyl 3,4-diphenylmuconates. The Journal of Organic Chemistry 40(4): 492-495
Baše, T.; Macháček, J.; Hájková, Z.; Langecker, J.; Kennedy, J.D.; Carr, M.J. 2015: Thermal isomerizations of monothiolated carboranes (HS)C 2 B 10 H 11 and the solid-state investigation of 9-(HS)-1,2-C 2 B 10 H 11 and 9-(HS)-1,7-C 2 B 10 H 11. Journal of Organometallic Chemistry 798: 132-140
Baldwin, J.E. 1998: Thermal isomerizations of vinylcyclopropanes to cyclopentenes. Journal of Computational Chemistry 19(2): 222-231
Ruiz, J.; Fairén, A.G.; Dohm, J.M.; Tejero, R. 2004: Thermal isostasy and deformation of possible paleoshorelines on Mars. Planetary and Space Science 52(14): 1297-1301
Liu, H.; Wei, Z.; He, W.; Zhao, J. 2017: Thermal issues about Li-ion batteries and recent progress in battery thermal management systems: a review. Energy Conversion and Management 150: 304-330
Alaluss, K.; Bürkner, G. 2018: Thermal joining of steel/polymer/steel composite materials using non-direct arcprocess technique. Journal of Manufacturing Processes 34: 523-530
Kohl, M.; Schricker, K.; Bergmann, J.P.; Lohse, M.; Hertel, M.; Füssel, U. 2018: Thermal joining of thermoplastics to metals: Surface preparation of steel based on laser radiation and tungsten inert gas arc process. Procedia CIRP 74: 500-505
Bullot, J.; Ceccaldi, D.; Szwarc, H. 1975: Thermal jump measurement of the activation energy of trapped electrons in 3-methylpentane glass. Chemical Physics Letters 34(3): 528-531
Zakout, I.; Greiner, W.; Jaqaman, H. 2005: Thermal kaon production in relativistic heavy-ion collisions. Nuclear Physics A 759(1-2): 201-226
Zhang, H.; Yu, H.; Chen, Z.; Luo, H.; Gao, Y. 2016: Thermal kinetic analysis of metal–insulator transition mechanism in W-doped VO2. Journal of Thermal Analysis and Calorimetry 126(2): 949-957
Sopacı, .B.; Nazır, H.; Emir, E.; Atakol, O.; Öz, S. 2017: Thermal kinetic analysis, theoretical thermodynamic calculations and antimicrobial activity of three new energetic materials. Journal of Thermal Analysis and Calorimetry 131(3): 3105-3120
Gorbachev, M. 2006: Thermal kinetic energy of liquids with conformationally rigid molecules. Physics and Chemistry of Liquids 44(2): 145-152
Faverzani, M.; Cruciani, A.; D'Addabbo, A.; Day, P.; Di Domizio, S.; Ferri, E.; Fresch, P.; Giachero, A.; Margesin, B.; Mezzena, R.; Minutolo, L.; Nucciotti, A.; Puiu, A.; Vignati, M. 2019: Thermal kinetic inductance detectors for soft X-ray spectroscopy. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 936: 197-198
Liu, Y.; Jiang, Y.; Zhang, T.; Feng, C.; Yang, L. 2014: Thermal kinetic performance and storage life analysis of a series of high-energy and green energetic materials. Journal of Thermal Analysis and Calorimetry 119(1): 659-670
Du, X.; Li, X.; Zou, M.; Yang, R.; Pang, S. 2013: Thermal kinetic study of 1-amino-1,2,3-triazolium nitrate. Journal of Thermal Analysis and Calorimetry 115(2): 1195-1203
Rambabu, K.; Semagina, N.; Lange, C.F. 2016: Thermal kinetics analysis in microwave-assisted oil sands separation. The Canadian Journal of Chemical Engineering 95(1): 127-135
Wang, Y.; Zhang, Y.; Zhou, Q.; Zhang, Y.; Sun, J. 2017: Thermal kinetics analysis of coal-gangue selected from Inner Mongolia in China. Journal of Thermal Analysis and Calorimetry 131(2): 1835-1843
Du, X.; Li, X.; Yang, R.; Li, Y.; Pang, S. 2014: Thermal kinetics and decomposition mechanism of 1-amino-1,2,3-triazolium nitrate. Chemical Research in Chinese Universities 30(1): 130-136
Shao, X.; Ji, X.; Min, S.; Liu, J.; Wang, W. 2014: Thermal kinetics and decomposition mechanism of methylphenylphosphinic acid and diphenylphosphinic acid. Chemical Research in Chinese Universities 30(6): 1028-1031
Mahendran, R.; Babu, S.K.; Natarajan, S.; Vallimanalan, A.; Manivannan, S. 2017: Thermal kinetics and phase stability of 8 mol% samaria doped zirconia nanopowders prepared via reverse coprecipitation. Ceramics International 43(11): 8051-8056
Wei, J.; Zhang, X.; Qiu, J.; Weeks, B.L. 2015: Thermal kinetics and thermo-mechanical properties of graphene integrated fluoroelastomer. Journal of Polymer Science Part B: Polymer Physics 53(23): 1691-1700
Moliner, C.; Badia, J.; Bosio, B.; Arato, E.; Teruel-Juanes, R.; Kittikorn, T.; Strömberg, E.; Ek, M.; Karlsson, S.; Ribes-Greus, A. 2018: Thermal kinetics for the energy valorisation of polylactide/sisal biocomposites. Thermochimica Acta 670: 169-177
Sharma, P.; Pandey, O.P. 2020: Thermal kinetics involved during the solid-state synthesis of Cr2Al C MAX phase. Journal of Thermal Analysis and Calorimetry 143(6): 3997-4008
Zhu, F.; Xu, Y.; Feng, Q.; Yang, Q. 2017: Thermal kinetics study and flammability evaluation of polyimide fiber material. Journal of Thermal Analysis and Calorimetry 131(3): 2579-2587
Ni, J.; Jia, H.; Pu, W.; Jiang, H.; Yang, J.; Ren, Q. 2014: Thermal kinetics study of light oil oxidation using TG/DTG techniques. Journal of Thermal Analysis and Calorimetry 117(3): 1349-1355
Malyj, M.; Smith, P.D.; Balko, B.; Berger, R.L. 1980: Thermal kinetics using a modified commercial stopped flow apparatus. Review of Scientific Instruments 51(7): 896-899
Alavéz-Ramírez, R.; Chiñas-Castillo, F.; Morales-Domínguez, V.J.; Ortiz-Guzmán, M.; Caballero-Montes, J.L.; Caballero-Caballero, M. 2016: Thermal lag and decrement factor of constructive component reinforced mortar channels filled with soil–cement–sawdust. Indoor and Built Environment 27(4): 466-485
Tzou, D.Y.; Dai, W. 2009: Thermal lagging in multi-carrier systems. International Journal of Heat and Mass Transfer 52(5-6): 1206-1213
Steel, E.A.; Marsha, A.; Fullerton, A.H.; Olden, J.D.; Larkin, N.K.; Lee, S.; Ferguson, A. 2019: Thermal landscapes in a changing climate: biological implications of water temperature patterns in an extreme year. Canadian Journal of Fisheries and Aquatic Sciences 76(10): 1740-1756
Vazquez-Martinez, J.; Botana, M.; Botana, F.; Del Sol, I.; Salguero, J.; Marcos, M. 2017: Thermal laser oxidation based texturing as finishing treatment for improving surface properties of UNS R56400. Procedia Manufacturing 13: 372-379
Beauchêne, T.; Lewis, D.; Beaudoin, F.; Pouget, V.; Desplats, R.; Fouillat, P.; Perdu, P.; Bafleur, M.; Tremouilles, D. 2003: Thermal laser stimulation and NB-OBIC techniques applied to ESD defect localization. Microelectronics Reliability 43(3): 439-444
Wei, W.; Sun, X.; Ye, W.; Zhang, B.; Fei, X.; Li, X.; Liu, X. 2020: Thermal latent curing agent for epoxy resins from neutralization of 2‐methylimidazole with a phosphazene‐containing polyfunctional carboxylic acid. Polymers for Advanced Technologies 31(7): 1553-1561
Soe, M.; Vahala, G.; Pavlo, P.; Vahala, L.; Chen, H. 1998: Thermal lattice Boltzmann simulations of variable Prandtl number turbulent flows. Physical Review E 57(4): 4227-4237
Chang, X.; Huang, H.; Lu, X. 2017: Thermal lattice Boltzmann study of three-dimensional bubble growth in quiescent liquid. Computers-Fluids 159: 232-242
Yamaguchi, S. 2003: Thermal lattice expansion behavior of Yb-doped Ba Ce O3. Solid State Ionics 162-163: 23-29
Thieme, S.; Degiorgi, L.; Grüner, G.; Wachter, P. 1995: Thermal lattice fluctuations in (Ta Se4)2l. Synthetic Metals 70(1-3): 1305-1306
Marinotto, D.; Danelli, S.G.; Giaretta, A.; Lucenti, E.; Stadler, P.; Tordin, E.; Mattei, G.; Scavia, G.; Ugo, R.; Cariati, E. 2016: Thermal layer-by-layer preparation of oriented films of a Cu(i) ionic inorganic–organic hybrid material showing semiconducting and SHG properties. Journal of Materials Chemistry C 4(29): 7077-7082
Son, J.; Stemmer, S. 2008: Thermal leakage characteristics of Pt∕Sr Ti O3∕Pt structures. Journal of Vacuum Science-Technology A: Vacuum, Surfaces, and Films 26(3): 555-557
Myers, K.F.; Doran, P.T.; Tulaczyk, S.M.; Foley, N.T.; Bording, T.S.; Auken, E.; Dugan, H.A.; Mikucki, J.A.; Foged, N.; Grombacher, D.; Virginia, R.A. 2021: Thermal legacy of a large paleolake in Taylor Valley, East Antarctica, as evidenced by an airborne electromagnetic survey. The Cryosphere 15(8): 3577-3593
Badran, H.A. 2014: Thermal lens and all optical switching of new organometallic compound doped polyacrylamide gel. Results in Physics 4: 69-72
Liang, P.; Hua, R.; Shen, Q. 1995: Thermal lens and its effects in copper-vapor lasers. Applied Physics B Lasers and Optics 60(6): 557-563
Messias, D.; Zanatta, A.; Catunda, T. 2004: Thermal lens and non-linear optical absorption study of a-Si H films. Journal of Non-Crystalline Solids 348: 230-234
Dovichi, N.J.; Harris, J.M. 1981: Thermal lens calorimetry for flowing samples. Analytical Chemistry 53(4): 689-692
Schwarz, J.; Ramsey, M.; Headley, D.; Rambo, P.; Smith, I.; Porter, J. 2005: Thermal lens compensation by convex deformation of a flat mirror with variable annular force. Applied Physics B 82(2): 275-281
Du, T.; Yuan, S.; Luo, W. 1994: Thermal lens coupled magneto‐optical effect in a ferrofluid. Applied Physics Letters 65(14): 1844-1846
Buffett, C.E.; Morris, M.D. 1982: Thermal lens detection for liquid chromatography. Analytical Chemistry 54(11): 1824-1825
Dudko, V.S.; Smirnova, A.P.; Proskurnin, M.A.; Hibara, A.; Kitamori, T. 2012: Thermal lens detection in microfluidic chips. Russian Journal of General Chemistry 82(12): 2146-2153
Ozygus, B.; Zhang, Q. 1997: Thermal lens determination of end-pumped solid-state lasers using primary degeneration modes. Applied Physics Letters 71(18): 2590-2592
Ozygus, B.; Erhard, J. 1995: Thermal lens determination of end‐pumped solid‐state lasers with transverse beat frequencies. Applied Physics Letters 67(10): 1361-1362
Andrade, A.A.; Catunda, T.; Bodnar, I.; Mura, J.; Baesso, M.L. 2003: Thermal lens determination of the temperature coefficient of optical path length in optical materials. Review of Scientific Instruments 74(1): 877-880
Giglio, M.; Vendramini, A. 1974: Thermal lens effect in a binary liquid mixture: a new effect. Applied Physics Letters 25(10): 555-557
Eichhorn, M. 2008: Thermal lens effects in an Er3+:YAG laser with crystalline fiber geometry. Applied Physics B 94(3): 451-457
Anjos, V.; Andrade, A.; Bell, M. 2008: Thermal lens investigation in amorphous Si N. Applied Surface Science 255(3): 698-700
Zou, J.; Zhao, S.; Yang, K.; Li, G.; Song, P. 2005: Thermal lens measurement of a LD end-pumped Nd: Gd VO4 laser with stable resonator by a slit-scanning method. Optoelectronics Letters 1(2): 113-116
Kapoor, R.; Mukhopadhyay, P.K.; George, J.; Sharma, S.K. 1999: Thermal lens measurement technique in end-pumped solid state lasers: Application to diode-pumped microchip lasers. Pramana 52(6): 623-629
Wang, Z.; Du, C.; Ruan, S.; Zhang, L. 2010: Thermal lens measurements in a Nd:Gd VO4 self-Raman laser. Optics-Laser Technology 42(6): 873-877
Wei, J.; Gan, F. 2003: Thermal lens model of Sb thin film in super-resolution near-field structure. Applied Physics Letters 82(16): 2607-2609
Rohling, J.H.; Caldeira, A.M.F.; Pereira, J.R.D.; Medina, A.N.; Bento, A.C.; Baesso, M.L.; Miranda, L.C.M.; Rubira, A.F. 2001: Thermal lens scanning of the glass transition in polymers. Journal of Applied Physics 89(4): 2220-2226
Mazza, G.; Posnicek, T.; Wagner, L.; Ettenauer, J.; Zuser, K.; Gusenbauer, M.; Brandl, M. 2017: Thermal lens spectrometry applied for a sensitive detection of silver-stained protein bands in polyacrylamide gels. Sensors and Actuators B: Chemical 249: 731-737
Miyaishi, K.; Imasaka, T.; Ishibashi, N. 1982: Thermal lens spectrometry based on image detection of a probe laser beam. Analytical Chemistry 54(12): 2039-2044
Almeida, A.S.; Rivera, G.; Sousa, C.A.; Santos, F.E.P.; Souza, D.N. 2019: Thermal lens spectroscopy dosimetry at high doses using a commercial transparent glass. Radiation Measurements 124: 85-90
Kassab, L.; Del Cacho, V.; Bell, M.; Messias, D.; de Oliveira, S.; Catunda, T. 2006: Thermal lens study of Pb O–Bi2O3–Ga2O3–Ba O glasses doped with Yb3+. Journal of Non-Crystalline Solids 352(32-35): 3647-3652
Zidan, M.D.; Al-Ktaifani, M.M.; El-Daher, M.S.; Allahham, A.; Ghanem, A. 2021: Thermal lens study of the Tris(2,2′-bipyridyl)iron(II) tetrafluoroborate. Optoelectronics Letters 17(3): 183-186
Rohling, J.H.; Pereira, J.R.D.; Medina, A.N.; Bento, A.C.; Baesso, M.L.; Sampaio, J.A.; Lima, S.M.; Catunda, T.; Miranda, L.C.M. 2003: Thermal lens temperature scanning for quantitative measurements in transparent materials (invited). Review of Scientific Instruments 74(1): 291-296
Hung, J.; Marcano O, A.; Castillo, J.; González, J.; Piscitelli, V.; Reyes, A.; Fernández, A. 2004: Thermal lensing and absorbance spectra of a fluorescent dye solution. Chemical Physics Letters 386(1-3): 206-210
Wu, C.; Chen, F.; Wang, R.; Ju, Y. 2014: Thermal lensing and laser performance of Tm:Lu AG crystal at room temperature. Optics Communications 333: 115-119
Gaponenko, M.S.; Loiko, P.A.; Gusakova, N.V.; Yumashev, K.V.; Kuleshov, N.V.; Pavlyuk, A.A. 2012: Thermal lensing and microchip laser performance of N g-cut Tm3+:KY(WO4)2 crystal. Applied Physics B 108(3): 603-607
Degallaix, J.; Zhao, C.; Ju, L.; Blair, D. 2004: Thermal lensing compensation for AIGO high optical power test facility. Classical and Quantum Gravity 21(5): S903-S908
Degallaix, J.; Slagmolen, B.; Zhao, C.; Ju, L.; Blair, D. 2005: Thermal lensing compensation principle for the ACIGA's High Optical Power Test Facility Test 1. General Relativity and Gravitation 37(9): 1581-1589
Alvarez, E R.; Camarillo, I G.; Castaño, E T.; Muñoz, A F.; Clark, A B.; Taheri, B. 1996: Thermal lensing effects in -doped luminescent glass. Journal of Physics: Condensed Matter 8(30): 5643-5648
Brunner, M.; Gulden, K.; Hövel, R.; Moser, M.; Ilegems, M. 2000: Thermal lensing effects in small oxide confined vertical-cavity surface-emitting lasers. Applied Physics Letters 76(1): 7-9
Omatsu, T.; Okida, M.; Lee, A.; Pask, H.M. 2012: Thermal lensing in a diode-end-pumped continuous-wave self-Raman Nd-doped Gd VO4 laser. Applied Physics B 108(1): 73-79
Tomaru, T.; Suzuki, T.; Miyoki, S.; Uchiyama, T.; Taylor, C T.; Yamamoto, A.; Shintomi, T.; Ohashi, M.; Kuroda, K. 2002: Thermal lensing in cryogenic sapphire substrates. Classical and Quantum Gravity 19(7): 2045-2049
Yumashev, K.; Loiko, P. 2015: Thermal lensing in diode-pumped [001]-cut tetragonal crystals. Optics Communications 355: 543-550
Strain, K.; Danzmann, K.; Mizuno, J.; Nelson, P.; Rüdiger, A.; Schilling, R.; Winkler, W. 1994: Thermal lensing in recycling interferometric gravitational wave detectors. Physics Letters A 194(1-2): 124-132
Lévesque, L.; Sabat, R.G. 2011: Thermal lensing investigation on bulk ceramics and thin-film PLZT using visible and far-infrared laser beams. Optical Materials 33(3): 460-465
Chénais, S.; Druon, F.; Balembois, F.; Lucas-Leclin, G.; Fichot, Y.; Georges, P.; Gaumé, R.; Viana, B.; Aka, G.; Vivien, D. 2003: Thermal lensing measurements in diode-pumped Yb-doped Gd COB, YCOB, YSO, YAG and KGW. Optical Materials 22(2): 129-137
Blows, J.L.; Dawes, J.M.; Omatsu, T. 1998: Thermal lensing measurements in line-focus end-pumped neodymium yttrium aluminium garnet using holographic lateral shearing interferometry. Journal of Applied Physics 83(6): 2901-2906
Hussain, M.; Imran, T.; Börzsönyi, . 2019: Thermal lensing measurements of Ti: sapphire crystal by an optical wavefront sensor. Microwave and Optical Technology Letters 61(12): 2901-2909
Loiko, P.A.; Yumashev, K.V.; Kuleshov, N.V.; Pavlyuk, A.A. 2011: Thermal lensing study and athermal directions in flashlamp-pumped Nd:KGd(WO4)2 laser crystal. Applied Physics B 106(4): 881-886
Fuke, K.; Ueda, M.; Itoh, M. 1983: Thermal lensing study of singlet oxygen reactions. Journal of the American Chemical Society 105(5): 1091-1096
Sakka, T.; Matsumura, K.; Tsuboi, T.; Ogata, Y. H. 1998: Thermal lensing study on the vibrational relaxation of highly excited chlorofluoroethane. Chemical Physics Letters 286(1-2): 107-112
Flannery, M.; Marburger, J. 1974: Thermal lensing with acentric beams in thin windows. IEEE Journal of Quantum Electronics 10(9): 766-767
Kliger, D.S. 1980: Thermal lensing: a new spectroscopic tool. Accounts of Chemical Research 13(5): 129-134
Dikandé, A.M.; Aban, E.C.; Sunda‐Meya, A. 2021: Thermal lensing‐induced soliton molecules in β ‐phase gallium oxide. Microwave and Optical Technology Letters 63(12): 3100-3107
Chen, Z.; Shi, J.; Zeng, G. 2016: Thermal light ghost imaging based on morphology. Optics Communications 381: 63-71
Daybell, M.; White, K.; Theimer, O. 1968: Thermal light scattering by ionic crystals. Journal of Physics and Chemistry of Solids 29(6): 1077-1079
Mingjie Sun, M.S.; Xingdan He, X.H.; Mingfei Li, M.L.; and Ling'an Wu, a.L.W. 2016: Thermal light subwavelength diffraction using positive and negative correlations. Chinese Optics Letters 14(4): 040301-40305
Grishin, A.M.; Ignatenko, N.A. 1973: Thermal limit of heterogeneous combustion. Combustion, Explosion, and Shock Waves 9(2): 213-217
Hasegawa, F.; Aono, Y. 1973: Thermal limitation for CW output power of a Gunn diode. Solid-State Electronics 16(3): 337-344
Summers, H.D.; Rees, P. 1997: Thermal limitation of self-pulsation in 650 nm Al Ga in P laser diodes with an epitaxially integrated absorber. Applied Physics Letters 71(18): 2665-2667
DeVaux, L.; Kimura, H.; Sheets, M.; Renda, F.; Balon, J.; Chia, P.; Lockwood, A. 1975: Thermal limitations in Pb Sn Te detectors. Infrared Physics 15(4): 271-277
Chaturvedi, P.; Khokle, W. 1973: Thermal limitations of CW and pulsed silicon TRAPATT diodes. IEEE Transactions on Electron Devices 20(4): 353-362
Schwarz, W. 1987: Thermal limitations of the pumping speed of refrigerator cooled cryosurfaces ≥− 90 °C. Journal of Vacuum Science-Technology A: Vacuum, Surfaces, and Films 5(4): 2568-2571
Page, D. 1968: Thermal limitations of the thin film transistor. Solid-State Electronics 11(1): 87-97
Dusenbery, D.B.; Barr, J. 1980: Thermal limits and chemotaxis in mutants of the nematode Caenorhabditis elegans defective in thermotaxis. Journal of Comparative Physiology ? A 137(4): 353-356
Hoyland, J.; Cossins, A.R.; Hill, M.W. 1979: Thermal limits for behavioural function and resistance-adaptation of goldfish, Carassius auratus L. Journal of Comparative Physiology A 129(3): 241-246
Huenerlage, K.; Buchholz, F. 2015: Thermal limits of krill species from the high-Arctic Kongsfjord (Spitsbergen). Marine Ecology Progress Series 535: 89-98
Anthony, S.E.; Buddle, C.M.; Høye, T.T.; Sinclair, B.J. 2019: Thermal limits of summer-collected Pardosa wolf spiders (Araneae: Lycosidae) from the Yukon Territory (Canada) and Greenland. Polar Biology 42(11): 2055-2064
Terblanche, J.S.; Mitchell, K.A.; Uys, W.; Short, C.; Boardman, L. 2017: Thermal limits to survival and activity in two life stages of false codling moth Thaumatotibia leucotreta (Lepidoptera, Tortricidae). Physiological Entomology 42(4): 379-388
Obrecht, C.; Asinari, P.; Kuznik, F.; Roux, J. 2016: Thermal link-wise artificial compressibility method: GPU implementation and validation of a double-population model. Computers-Mathematics with Applications 72(2): 375-385
Li, L.; Sun, J.; Li, Y. 2017: Thermal load and bending analysis of heat collection element of direct-steam-generation parabolic-trough solar power plant. Applied Thermal Engineering 127: 1530-1542
Buttstädt, M.; Schneider, C. 2014: Thermal load in a medium-sized European city using the example of Aachen, Germany. Erdkunde 68(2): 71-83
Ingen Housz, J.F. 1977: Thermal load in the processing of thermoplastics. Polymer Engineering and Science 17(12): 828-831
Sodha, M.S.; Kumar, A.; Srivastava, A.; Tiwari, G.N. 1981: Thermal load levelling in a multilayered wall/roof. International Journal of Energy Research 5(1): 1-9
Sodha, M.S.; Bhardwaj, S.C.; Kaushik, S.C. 1981: Thermal load levelling of heat flux through an insulated thermal storage water wall. International Journal of Energy Research 5(2): 155-163
Chankin, A.; Chicherov, V.; Efstigneev, S.; Grashin, S.; Grote, H.; Crunow, C.; Günther, K.; Lingertat, J.; Kabashova, N.; Vershkov, V.; Zvonkov, S. 1987: Thermal load of a scoop limiter with changeable geometry. Journal of Nuclear Materials 145-147: 789-792
Guelpa, E.; Marincioni, L.; Capone, M.; Deputato, S.; Verda, V. 2019: Thermal load prediction in district heating systems. Energy 176: 693-703
Jamison, K.; Petresky, H.; Beavers, F.; Eggers, P.; Gunito, S.; Holland, M.; Vrable, D. 1995: Thermal loading and heat removal from a sequentially fired railgun. IEEE Transactions on Magnetics 31(1): 314-319
Eraslan, A.N.; Apatay, T. 2016: Thermal loading and unloading of a solid cylinder subjected to periodic internal energy cycling. ZAMM - Journal of Applied Mathematics and Mechanics / Zeitschrift für Angewandte Mathematik und Mechanik 97(3): 340-357
Ebrahimi, F.; Salari, E. 2016: Thermal loading effects on electro-mechanical vibration behavior of piezoelectrically actuated inhomogeneous size-dependent Timoshenko nanobeams. Advances in nano research 4(3): 197-228
Alifenov, O.M.; Gejadze, I.Y. 1997: Thermal loads identification technique for materials and structures in real time. Acta Astronautica 41(4-10): 255-265
Navarro, L.; de Garcia, A.; Solé, C.; Castell, A.; Cabeza, L.F. 2012: Thermal loads inside buildings with phase change materials: Experimental results. Energy Procedia 30: 342-349
Cecchi, J.; Coppi, B. 1984: Thermal loads on the ignitor limiter for elongated plasmas. Journal of Nuclear Materials 121: 449-452
Karasu, S.; Toker, O.S.; Yilmaz, M.T.; Karaman, S.; Dertli, E. 2015: Thermal loop test to determine structural changes and thermal stability of creamed honey: Rheological characterization. Journal of Food Engineering 150: 90-98
Posch, S.; Hopfgartner, J.; Dür, L.; Eichinger, M.; Stangl, S.; Almbauer, R. 2018: Thermal loss analysis of hermetic compressors using numerical simulation. Applied Thermal Engineering 130: 1580-1589
Caporal Del Barrio, S.; Morris, A.; Pedersen, G.F. 2015: Thermal loss becomes an issue for narrow‐band tunable antennas in fourth generation handsets. IET Microwaves, Antennas-Propagation 9(10): 1015-1020
Büttner, D.; Caps, R.; Heinemann, U.; Hümmer, E.; Kadur, A.; Fricke, J. 1988: Thermal loss coefficients of low-density silica aerogel tiles. Solar Energy 40(1): 13-15
Hirakawa, Y.; Tomooka, T.; Imasaka, T. 2000: Thermal loss mechanism in the generation of multifrequency laser emission via stimulated Raman scattering and four-wave Raman mixing studied by photothermal refraction spectroscopy. Applied Physics B: Lasers and Optics 70(3): 355-359
Qaisrani, M.A.; Fang, J.; Jin, Y.; Wan, Z.; Tu, N.; Khalid, M.; Rahman, M.U.; Wei, J. 2019: Thermal losses evaluation of an external rectangular receiver in a windy environment. Solar Energy 184: 281-291
Ishii, H.; Satoh, C.; Yamada, T.; Karakisawa, T.; Sekine, M.; Nakata, M. 2010: Thermal luminescence spectra of lysine and phenylalanine in O2 measured with a Fourier-transform chemiluminescence spectrometer. Chemical Physics Letters 496(4-6): 330-334
Potekhin, A Y.; Zyuzin, D A.; Yakovlev, D G.; Beznogov, M V.; Shibanov, Y. A. 2020: Thermal luminosities of cooling neutron stars. Monthly Notices of the Royal Astronomical Society 496(4): 5052-5071
Svedlindh, P.; Granberg, P.; Lundgren, L.; Nordblad, P.; Chen, H. 1987: Thermal magnetic fluctuations in metallic spin glasses. Physics Letters A 121(5): 237-240
Tsiantos, V.D.; Schrefl, T.; Scholz, W.; Fidler, J. 2003: Thermal magnetization noise in submicrometer spin valve sensors. Journal of Applied Physics 93(10): 8576-8578
Nick, W.; Schmidt, C. 1981: Thermal magnetoresistance of copper matrix in compound superconductors, a new measuring method. IEEE Transactions on Magnetics 17(1): 217-219
Gorter, F.; Miedema, A. 1968: Thermal magnetoresistance of gallium and its use as a heat switch. Cryogenics 8(2): 86-87
Chang, T.; Fuh, Y.; Lu, H.; Tu, S. 2015: Thermal management and performance evaluation of a dual bi-directional, soft-switched IGBT-based inverter for the 1st autonomous microgrid power system in Taiwan under various operating conditions. Heat and Mass Transfer 52(6): 1231-1241
Endo, N.; Goshome, K.; Tetsuhiko, M.; Segawa, Y.; Shimoda, E.; Nozu, T. 2021: Thermal management and power saving operations for improved energy efficiency within a renewable hydrogen energy system utilizing metal hydride hydrogen storage. International Journal of Hydrogen Energy 46(1): 262-271
Lefranc, G.; Mitic, G.; Schultz, H. 2001: Thermal management and reliability of multi-chip power modules. Microelectronics Reliability 41(9-10): 1663-1669
Hassan, A.; Wahab, A.; Qasim, M.A.; Janjua, M.M.; Ali, M.A.; Ali, H.M.; Jadoon, T.R.; Ali, E.; Raza, A.; Javaid, N. 2020: Thermal management and uniform temperature regulation of photovoltaic modules using hybrid phase change materials-nanofluids system. Renewable Energy 145: 282-293
Huangfu, Y.; Wu, J.; Wang, R.; Li, S. 2009: Thermal management controller for heat source temperature control and thermal management. Journal of Shanghai Jiaotong University (Science) 14(1): 58-63
Petley, D.H.; Jones, S.C. 1992: Thermal management for a Mach 5 cruise aircraft using endothermic fuel. Journal of Aircraft 29(3): 384-389
Seo, S.; Oh, S.; Oh, H.; Kim, M.; Lee, W.; Kwak, H. 2019: Thermal management for a hydrogen-fueled 1-k W PEMFC based on thermoeconomic analysis. International Journal of Hydrogen Energy 44(45): 24934-24946
Alaoui, C. 2017: Thermal management for energy storage system for smart grid. Journal of Energy Storage 13: 313-324
Sheikholeslami, M.; Gorji-Bandpy, M.; Ganji, D.; Soleimani, S. 2014: Thermal management for free convection of nanofluid using two phase model. Journal of Molecular Liquids 194: 179-187
Lan, C.; Xu, J.; Qiao, Y.; Ma, Y. 2016: Thermal management for high power lithium-ion battery by minichannel aluminum tubes. Applied Thermal Engineering 101: 284-292
Kolias, N.; Compton, R. 1996: Thermal management for high-power active amplifier arrays. IEEE Transactions on Microwave Theory and Techniques 44(6): 963-966
Kato, R.; Naya, M.; Kasahata, N.; Senga, R.; Sato, C.; Koshino, M.; Suenaga, K.; Hasegawa, M. 2021: Thermal management function of graphene under cryogenic temperature. Carbon 183: 970-976
Mohammadian, S.K.; Rassoulinejad-Mousavi, S.M.; Zhang, Y. 2015: Thermal management improvement of an air-cooled high-power lithium-ion battery by embedding metal foam. Journal of Power Sources 296: 305-313
Keramati, M.; Modarressi, M.; Rezaei, S.H.S. 2017: Thermal management in 3d networks-on-chip using dynamic link sharing. Microprocessors and Microsystems 52: 69-79
Kiran Sanipini, V.; Rakesh, B.; Jyothi Chamanthula, A.; Santoshi, N.; Arunkumar Gudivada, A.; Kumar Panigrahy, A. 2021: Thermal management in TSV based 3D IC Integration: a survey. Materials Today: Proceedings 45: 1742-1746
Scotti, F.M.; Teixeira, F.R.; Silva, L.J.d.; de Araújo, D.B.; Reis, R.P.; Scotti, A. 2020: Thermal management in WAAM through the CMT Advanced process and an active cooling technique. Journal of Manufacturing Processes 57: 23-35
Seo, J.; Khajepour, A.; Huissoon, J.P. 2014: Thermal management in laminated die system. International Journal of Control, Automation and Systems 12(4): 794-804
Fang, G.; Yuan, W.; Yan, Z.; Sun, Y.; Tang, Y. 2019: Thermal management integrated with three-dimensional heat pipes for air-cooled permanent magnet synchronous motor. Applied Thermal Engineering 152: 594-604
Wang, Z.; Li, X.; Zhang, G.; Lv, Y.; Wang, C.; He, F.; Yang, C.; Yang, C. 2017: Thermal management investigation for lithium-ion battery module with different phase change materials. RSC Advances 7(68): 42909-42918
Das, D.; Basak, T. 2017: Thermal management investigation on fluid processing within porous rhombic cavities: Heatlines versus entropy generation. The Canadian Journal of Chemical Engineering 95(7): 1399-1416
Reiser, J.; Hoffmann, A.; Hain, J.; Jäntsch, U.; Klimenkov, M.; Hohe, J.; Mrotzek, T. 2019: Thermal management materials based on molybdenum (Mo) and copper (Cu): Elucidation of the rolling-induced evolution of thermo-physical properties (e.g. CTE). Journal of Alloys and Compounds 776: 387-416
Bai, F.; Chen, M.; Song, W.; Li, Y.; Feng, Z.; Li, Y. 2019: Thermal management of 48 V standby battery for outdoor base station at cold environment. Energy Procedia 158: 4224-4231
Kosaka, F.; Yamaguchi, T.; Ando, Y.; Mochizuki, T.; Takagi, H.; Matsuoka, K.; Kuramoto, K. 2021: Thermal management of CO2 methanation with axial staging of active metal concentration in Ni-YSZ tubular catalysts. International Journal of Hydrogen Energy 46(5): 4116-4125
Huang, Y.; Cheng, W.; Zhao, R. 2019: Thermal management of Li-ion battery pack with the application of flexible form-stable composite phase change materials. Energy Conversion and Management 182: 9-20
Yang, X.; Tan, S.; Liu, J. 2016: Thermal management of Li-ion battery with liquid metal. Energy Conversion and Management 117: 577-585
Alkanhal, T.A.; Sheikholeslami, M.; Usman, M.; Haq, R.; Shafee, A.; Al-Ahmadi, A.S.; Tlili, I. 2019: Thermal management of MHD nanofluid within the porous medium enclosed in a wavy shaped cavity with square obstacle in the presence of radiation heat source. International Journal of Heat and Mass Transfer 139: 87-94
Azizi, Y.; Sadrameli, S. 2016: Thermal management of a Li Fe PO4 battery pack at high temperature environment using a composite of phase change materials and aluminum wire mesh plates. Energy Conversion and Management 128: 294-302
Ren, Y.; Yu, Z.; Song, G. 2017: Thermal management of a Li-ion battery pack employing water evaporation. Journal of Power Sources 360: 166-171
Sun, D.; Simakov, D.S. 2017: Thermal management of a Sabatier reactor for CO2 conversion into CH4: Simulation-based analysis. Journal of CO 2 Utilization 21: 368-382
Wang, H.; Ma, L. 2017: Thermal management of a large prismatic battery pack based on reciprocating flow and active control. International Journal of Heat and Mass Transfer 115: 296-303
Yang, S.; Chagas, M.; Ordonez, J. 2018: Thermal management of a notional all-electric ship electromagnetic launcher. Energy Conversion and Management 157: 339-350
Chethana, G.; Sadashive Gowda, B. 2021: Thermal management of air and liquid cooled data centres: a review. Materials Today: Proceedings 45: 145-149
Epting, J.; Händel, F.; Huggenberger, P. 2013: Thermal management of an unconsolidated shallow urban groundwater body. Hydrology and Earth System Sciences 17(5): 1851-1869
Naji, A.; Ahmed, Z.; Issam, S.; Said, D. 2021: Thermal management of an unloaded hybrid dryer by generalized predictive control. Drying Technology: 1-13
He, F.; Ma, L. 2015: Thermal management of batteries employing active temperature control and reciprocating cooling flow. International Journal of Heat and Mass Transfer 83: 164-172
Asefi, G.; Habibollahzade, A.; Ma, T.; Houshfar, E.; Wang, R. 2021: Thermal management of building-integrated photovoltaic/thermal systems: a comprehensive review. Solar Energy 216: 188-210
Radwan, A.; Ahmed, M. 2018: Thermal management of concentrator photovoltaic systems using microchannel heat sink with nanofluids. Solar Energy 171: 229-246
Zarma, I.; Emam, M.; Ookawara, S.; Ahmed, M. 2020: Thermal management of concentrator photovoltaic systems using nano‐enhanced phase change materials‐based heat sink. International Journal of Energy Research 44(9): 7713-7733
Rabie, R.; Emam, M.; Ookawara, S.; Ahmed, M. 2019: Thermal management of concentrator photovoltaic systems using new configurations of phase change material heat sinks. Solar Energy 183: 632-652
Sheikholeslami, M.; Hatami, M.; Jafaryar, M.; Farkhadnia, F.; Ganji, D.D.; Gorji-Bandpy, M. 2015: Thermal management of double-pipe air to water heat exchanger. Energy and Buildings 88: 361-366
Ali, H.M.; Arshad, A.; Jabbal, M.; Verdin, P. 2018: Thermal management of electronics devices with PCMs filled pin-fin heat sinks: a comparison. International Journal of Heat and Mass Transfer 117: 1199-1204
Ali, H.M.; Ashraf, M.J.; Giovannelli, A.; Irfan, M.; Irshad, T.B.; Hamid, H.M.; Hassan, F.; Arshad, A. 2018: Thermal management of electronics: An experimental analysis of triangular, rectangular and circular pin-fin heat sinks for various PCMs. International Journal of Heat and Mass Transfer 123: 272-284
Yin, Y.; Cui, Y.; Li, Y.; Xing, Y.; Li, M. 2018: Thermal management of flexible wearable electronic devices integrated with human skin considering clothing effect. Applied Thermal Engineering 144: 504-511
Chutani, R.; Galliou, S.; Passilly, N.; Gorecki, C.; Sitomaniemi, A.; Heikkinen, M.; Kautio, K.; Keränen, A.; Jornod, A. 2012: Thermal management of fully LTCC-packaged Cs vapour cell for MEMS atomic clock. Sensors and Actuators A: Physical 174: 58-68
Tang, Y.; Lin, L.; Zhang, S.; Zeng, J.; Tang, K.; Chen, G.; Yuan, W. 2017: Thermal management of high-power LEDs based on integrated heat sink with vapor chamber. Energy Conversion and Management 151: 1-10
Menale, C.; D'Annibale, F.; Mazzarotta, B.; Bubbico, R. 2019: Thermal management of lithium-ion batteries: An experimental investigation. Energy 182: 57-71
Tong, L.; Xiao, J.; Bénard, P.; Chahine, R. 2019: Thermal management of metal hydride hydrogen storage reservoir using phase change materials. International Journal of Hydrogen Energy 44(38): 21055-21066
Nguyen, H.Q.; Shabani, B. 2022: Thermal management of metal hydride hydrogen storage using phase change materials for standalone solar hydrogen systems: An energy/exergy investigation. International Journal of Hydrogen Energy 47(3): 1735-1751
Boobalakrishnan, P.; Manoj Kumar, P.; Balaji, G.; Jenaris, D.; Kaarthik, S.; Jaya Prakash Babu, M.; Karthhik, K. 2021: Thermal management of metal roof building using phase change material (PCM). Materials Today: Proceedings 47: 5052-5058
Chen, J.; Li, L. 2020: Thermal management of methanol reforming reactors for the portable production of hydrogen. International Journal of Hydrogen Energy 45(4): 2527-2545
Tariq, H.A.; Shoukat, A.A.; Hassan, M.; Anwar, M. 2018: Thermal management of microelectronic devices using micro-hole cellular structure and nanofluids. Journal of Thermal Analysis and Calorimetry 136(5): 2171-2182
Saravanan, V.; Kumaraguruparan, G. 2019: Thermal management of microwave electronics in the radar system. ISSS Journal of Micro and Smart Systems 8(2): 143-153
Bozada, C.; Cerny, C.; De Salvo, G.; Dettmer, R.; Ebel, J.; Gillespie, J.; Havasy, C.; Jenkins, T.; Ito, C.; Nakano, K.; Pettiford, C.; Quach, T.; Sewell, J.; Via, G.; Anholt, R. 1997: Thermal management of microwave power heterojunction bipolar transistors. Solid-State Electronics 41(10): 1667-1673
Afzal, A.; Mohammed Samee, A.D.; Abdul Razak, R.K.; Ramis, M.K. 2020: Thermal management of modern electric vehicle battery systems (MEVBS). Journal of Thermal Analysis and Calorimetry 144(4): 1271-1285
Khan, S.R.; Zeeshan, M.; Iqbal, S. 2018: Thermal management of newly developed non-noble metal-based catalytic converter to reduce cold start emissions of small internal combustion engine. Chemical Engineering Communications 205(5): 680-688
Lindberg, H.; Strassner, M.; Gerster, E.; Bengtsson, J.; Larsson, A. 2005: Thermal management of optically pumped long-wavelength in P-based semiconductor disk lasers. IEEE Journal of Selected Topics in Quantum Electronics 11(5): 1126-1134
Turkyilmazoglu, M. 2020: Thermal management of parabolic pin fin subjected to a uniform oncoming airflow: optimum fin dimensions. Journal of Thermal Analysis and Calorimetry 143(5): 3731-3739
Shyu, J.; Tsai, H. 2015: Thermal management of pico projector using a piezoelectric fan. Energy Conversion and Management 101: 172-180
Haque, S.; Stinnett, W.A.; Nelson, D.J.; Lu, G. 1999: Thermal management of power electronics modules packaged by a stacked-plate technique. Microelectronics Reliability 39(9): 1343-1349
Guo, Z.; Liang, X.; Zhang, X. 2001: Thermal management of space stations. Chinese Science Bulletin 46(23): 2019-2024
Song, W.; Bai, F.; Chen, M.; Lin, S.; Feng, Z.; Li, Y. 2018: Thermal management of standby battery for outdoor base station based on the semiconductor thermoelectric device and phase change materials. Applied Thermal Engineering 137: 203-217
Hamzah, H.; Albojamal, A.; Sahin, B.; Vafai, K. 2020: Thermal management of transverse magnetic source effects on nanofluid natural convection in a wavy porous enclosure. Journal of Thermal Analysis and Calorimetry 143(3): 2851-2865
Epting, J. 2017: Thermal management of urban subsurface resources - Delineation of boundary conditions. Procedia Engineering 209: 83-91
Ul Haq, R.; Naveed Kazmi, S.; Mekkaoui, T. 2017: Thermal management of water based SWCNTs enclosed in a partially heated trapezoidal cavity via FEM. International Journal of Heat and Mass Transfer 112: 972-982
Ul Haq, R.; Soomro, F.A.; Öztop, H.F.; Mekkaoui, T. 2019: Thermal management of water-based carbon nanotubes enclosed in a partially heated triangular cavity with heated cylindrical obstacle. International Journal of Heat and Mass Transfer 131: 724-736
Bahru, R.; Hamzah, A.A.; Mohamed, M.A. 2020: Thermal management of wearable and implantable electronic healthcare devices: Perspective and measurement approach. International Journal of Energy Research 45(2): 1517-1534
Arulprakasajothi, M.; Susanth, B.; Naveen Kumar, K.; Madan Mohan Reddy, A. 2021: Thermal management on external surfaces by thermochromic materials. Materials Today: Proceedings 47: 4666-4670
Wu, W.; Wu, W.; Wang, S. 2018: Thermal management optimization of a prismatic battery with shape-stabilized phase change material. International Journal of Heat and Mass Transfer 121: 967-977
Zheng, N.; Fan, R.; Sun, Z.; Zhou, T. 2020: Thermal management performance of a fin‐enhanced phase change material system for the lithium‐ion battery. International Journal of Energy Research 44(9): 7617-7629
Wang, T.; Zhang, X.; Zeng, Q.; Gao, K. 2020: Thermal management performance of cavity cold plates for pouch Li‐ion batteries using in electric vehicles. Energy Science-Engineering 8(11): 4082-4093
Xia, G.; Zhuang, D.; Ding, G. 2019: Thermal management solution for enclosed controller used in inverter air conditioner based on heat pipe heat sink. International Journal of Refrigeration 99: 69-79
Yetik, O.; Karakoc, T.H. 2021: Thermal management system with nanofluids for hybrid electric aircraft battery. International Journal of Energy Research 45(6): 8919-8931
Liu, J.; Wang, T.; Campbell, E. 2009: Thermal management technologies for electronics based on multiwalled carbon nanotube bundles. IEEE Nanotechnology Magazine 3(1): 16-19
Hernon, D.; Salamon, T.; Kempers, R.; Krishnan, S.; Lyons, A.; Hodes, M.; Kolodner, P.; Mullins, J.; McGarry, L. 2009: Thermal management: Enabling enhanced functionality and reduced carbon footprint. Bell Labs Technical Journal 14(3): 7-19
Astasio-Picado, A.; Escamilla Martínez, E.; Martínez Nova, A.; Sánchez Rodríguez, R.; Gómez–Martín, B. 2018: Thermal map of the diabetic foot using infrared thermography. Infrared Physics-Technology 93: 59-62
Szwarc, T.; Hubbard, S. 2014: Thermal mapping and trends of Mars analog materials in sample acquisition operations using experimentation and models. Planetary and Space Science 99: 158-166
Sawyer, D.; Berning, D. 1976: Thermal mapping of transistors with a laser scanner. Proceedings of the IEEE 64(11): 1634-1635
Csendes, A.; Székely, V.; Rencz, M. 1996: Thermal mapping with liquid crystal method. Microelectronic Engineering 31(1-4): 281-290
Tang, Y.; Li, S.; Zhang, F.; Fang, L. 2018: Thermal maps based HT detection using spatial projection transformation. IET Information Security 12(4): 356-361
Chudecka, M.; Lubkowska, A. 2015: Thermal maps of young women and men. Infrared Physics-Technology 69: 81-87
Madison, M.; McDaniel, T.; Nelson, J. 1989: Thermal mark characterization on static magneto-optical media. IEEE Transactions on Magnetics 25(5): 4045-4047
Eletsky, V.; Ioffe, B. 1997: Thermal mass shift of nucleons. Physics Letters B 401(3-4): 327-329
Pearce, R.; Ireland, P.; Romero, E. 2020: Thermal matching using Gaussian process regression. Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering 234(6): 1172-1180
Celotti, A.; Kuncic, Z.; Rees, M.J.; Wardle, J.F.C. 1998: Thermal material in relativistic jets. Monthly Notices of the Royal Astronomical Society 293(3): 288-298
Xiao, X.; Zhou, Q.; Cheng, P.; Sun, J.; Liu, D.; Tian, H. 2020: Thermal maturation as revealed by micro-Raman spectroscopy of mineral-organic aggregation (MOA) in marine shales with high and over maturities. Science China Earth Sciences 63(10): 1540-1552
Macchioli Grande, M.; Alasino, P.; Dahlquist, J.; Morales Cámera, M.; Galindo, C.; Basei, M. 2020: Thermal maturation of a complete magmatic plumbing system at the Sierra de Velasco, Northwestern Argentina. Geological Magazine 158(3): 537-554
Shalaby, M.R.; Malik, O.A.; Lai, D.; Jumat, N.; Islam, M.A. 2020: Thermal maturity and TOC prediction using machine learning techniques: case study from the Cretaceous–Paleocene source rock, Taranaki Basin, New Zealand. Journal of Petroleum Exploration and Production Technology 10(6): 2175-2193
Fonseca, C.; Mendonça, J.O.; Mendonça Filho, J.G.; Lézin, C.; Duarte, L.V. 2018: Thermal maturity assessment study of the late Pliensbachian-early Toarcian organic-rich sediments in southern France: Grands Causses, Quercy and Pyrenean basins. Marine and Petroleum Geology 91: 338-349
Kibria, M.G.; Das, S.; Hu, Q.; Basu, A.R.; Hu, W.; Mandal, S. 2020: Thermal maturity evaluation using Raman spectroscopy for oil shale samples of USA: comparisons with vitrinite reflectance and pyrolysis methods. Petroleum Science 17(3): 567-581
Zhang, M.; Li, Z. 2018: Thermal maturity of the Permian Lucaogou Formation organic-rich shale at the northern foot of Bogda Mountains, Junggar Basin (NW China): Effective assessments from organic geochemistry. Fuel 211: 278-290
Mani, D.; Patil, D.; Dayal, A.; Prasad, B. 2015: Thermal maturity, source rock potential and kinetics of hydrocarbon generation in Permian shales from the Damodar Valley basin, Eastern India. Marine and Petroleum Geology 66: 1056-1072
Kim, T.; Funaki, T. 2016: Thermal measurement and analysis of packaged Si C MOSFETs. Thermochimica Acta 633: 31-36
Schuster, G. 1976: Thermal measurement of AC power in comparison with the electrodynamic method. IEEE Transactions on Instrumentation and Measurement IM-25(4): 529-533
Bachinger, F.; Hamberger, P. 2017: Thermal measurement of an ester-filled power transformer at ultra-low temperatures: steady state. Procedia Engineering 202: 130-137
Angle, J.P.; Nelson, A.T.; Men, D.; Mecartney, M.L. 2014: Thermal measurements and computational simulations of three-phase (Ce O2–Mg Al2O4–Ce Mg Al11O19) and four-phase (3Y-TZP–Al2O3–Mg Al2O4–la PO4) composites as surrogate inert matrix nuclear fuel. Journal of Nuclear Materials 454(1-3): 69-76
Dubbs, T.; Kashigin, S.; Miller, W.; Rowe, W.; Sadrozinski, H.; Shih, W.; Seiden, A.; Webster, A.; Wichmann, R. 1997: Thermal measurements and simulations with a silicon detector-pyrolytic graphite sandwich. IEEE Transactions on Nuclear Science 44(3): 743-746
Wark, C.E.; Foss, J.F. 1988: Thermal measurements for jets in disturbed and undisturbed crosswindconditions. AIAA Journal 26(8): 901-902
Zanette, D.H.; Montemurro, M.A. 2003: Thermal measurements of stationary nonequilibrium systems: a test for generalized thermostatistics. Physics Letters A 316(3-4): 184-189
Tröltzsch, J.; Dippmann, C. 1981: Thermal measurements on chalcogenide glass threshold switching devices. Physica Status Solidi (a) 67(2): 527-531
Tian, Q.; Dong, X.; Hong, J. 2010: Thermal mechanical behavior and microstructure characteristic of microalloyed Cr Mo steel under cross deformation. Materials Science and Engineering: A527(18-19): 4702-4707
Zambrini, J.; Yasue, K. 1980: Thermal mechanics: a quantum mechanical analogue of nonequilibrium statistical thermodynamics. Annals of Physics 125(1): 176-192
Craciun, V.; Craciun, D. 1997: Thermal mechanisms in laser ablation of Ga as. Applied Surface Science 109-110: 312-316
Ionin, A.A.; Kudryashov, S.I. 2016: Thermal melting and ablation dynamics on a femtosecond laser-heated highly-oriented pyrolytic graphite surface. JETP Letters 104(8): 573-577
Wei, J.; Sun, Z.; Zhang, F.; Xu, W.; Wang, Y.; Zhou, F.; Gan, F. 2004: Thermal melting of solid materials induced by ultrafast laser pulse irradiation as explosively homogeneous nucleation. Chemical Physics Letters 392(4-6): 415-418
Tasaka, M. 1978: Thermal membrane potential across mosaic membranes. Journal of Membrane Science 4: 51-59
Tasaka, M. 1986: Thermal membrane potential and thermoosmosis across charged membranes. Pure and Applied Chemistry 58(12): 1637-1646
Boumaiza, S.; Ghannouchi, F. 2003: Thermal memory effects modeling and compensation in RF power amplifiers and predistortion linearizers. IEEE Transactions on Microwave Theory and Techniques 51(12): 2427-2433
Ţolea, F.; Ţolea, M.; Văleanu, M. 2017: Thermal memory fading by heating to a lower temperature: Experimental data on polycrystalline Ni Fe Ga ribbons and 2D statistical model predictions. Solid State Communications 257: 36-41
Gunaratne, L.M.W.K.; Shanks, R.A. 2005: Thermal memory of poly(3-hydroxybutyrate) using temperature-modulated differential scanning calorimetry. Journal of Polymer Science Part B: Polymer Physics 44(1): 70-78
Cohades, A.; Michaud, V. 2017: Thermal mending in E-glass reinforced poly(ε-caprolactone)/epoxy blends. Composites Part A: Applied Science and Manufacturing 99: 129-138
Cohades, A.; Manfredi, E.; Plummer, C.J.; Michaud, V. 2016: Thermal mending in immiscible poly(ε-caprolactone)/epoxy blends. European Polymer Journal 81: 114-128
Mahmood, H.; Dorigato, A.; Pegoretti, A. 2020: Thermal mending in novel epoxy/cyclic olefin copolymer blends. Express Polymer Letters 14(4): 368-383
Cheon, J.; Kiran, D.V.; Na, S. 2016: Thermal metallurgical analysis of GMA welded AH36 steel using CFD–FEM framework. Materials-Design 91: 230-241
Sklan, S. R.; Li, B. 2018: Thermal metamaterials: functions and prospects. National Science Review 5(2): 138-141
Yesiltas, M.; Young, J.; Glotch, T.D. 2021: Thermal metamorphic history of Antarctic CV3 and CO3 chondrites inferred from the first- and second-order Raman peaks of polyaromatic organic carbon. American Mineralogist 106(4): 506-517
Hiroi, T.; Zolensky, M.E.; Pieters, C.M.; Lipschutz, M.E. 1996: Thermal metamorphism of the C, G, B, and F asteroids seen from the 0.7 μm, 3 μm, and UV absorption strengths in comparison with carbonaceous chondrites. Meteoritics-Planetary Science 31(3): 321-327
Deryagina, E.N.; Voronkov, M.G. 2000: Thermal methods for the synthesis of thiophene, selenophene, and their derivatives. (Review). Chemistry of Heterocyclic Compounds 36(1): 1-14
Labus, M. 2017: Thermal methods implementation in analysis of fine-grained rocks containing organic matter. Journal of Thermal Analysis and Calorimetry 129(2): 965-973
Tungler, A. 2005: Thermal methods in the investigation of nickel catalysts. Journal of Thermal Analysis and Calorimetry 79(3): 521-524
Sarge, S. 1997: Thermal methods of analysis, principles, applications and problems. Thermochimica Acta 307(2): 205-206
Weber-Anneler, H.; Arndt, R. 1985: Thermal methods of analysis/differential scanning calorimetry in theory and application. Thermochimica Acta 85: 271-274
Bradshaw, P. 1968: Thermal methods of flow measurement. Journal of Physics E: Scientific Instruments 1(5): 504-509
Polaczek, J.; Machowska, Z. 1996: Thermal methods of the raw material recycling of plastics wast. Polimery 41(02): 69-74
Ponomarev, D.A.; Spitsyn, A.A.; Piyalkin, V.N. 2012: Thermal methods to obtain liquid fuels and other products from wood. Russian Journal of General Chemistry 82(5): 1006-1012
Yokoyama, Y.; Takeda, M.; Umemoto, T.; Ogushi, T. 2004: Thermal micro pumps for a loop-type micro channel. Sensors and Actuators A: Physical 111(1): 123-128
Zamir, S.; Meyler, B.; Salzman, J. 2001: Thermal microcrack distribution control in Ga N layers on Si substrates by lateral confined epitaxy. Applied Physics Letters 78(3): 288-290
Nishi, T.; Yamamoto, S.; Okawa, M.; Hatori, K.; Ikeda, T.; Ohta, H. 2018: Thermal microscope measurement of thermal effusivity distribution in compositionally graded Pb Te–Sb 2 Te 3 –Ag 2 Te alloy system. Thermochimica Acta 659: 39-43
Heiderhoff, R.; Makris, A.; Riedl, T. 2016: Thermal microscopy of electronic materials. Materials Science in Semiconductor Processing 43: 163-176
Lederman, M.; Richardson, D.; Tong, H. 1997: Thermal microscopy of spin-valve and magnetoresistive devices. IEEE Transactions on Magnetics 33(5): 2923-2925
Grudin, O.; Frolov, G.; Katsan, I.; Lupina, B. 1997: Thermal microsensor with a.c. heating for gas-pressure measurements. Sensors and Actuators A: Physical 62(1-3): 571-575
Avilés, F.; Ceh, O.; Oliva, A.I. 2003: Thermal microstrains measured by atomic force microscopy. Review of Scientific Instruments 74(7): 3356-3361
Baltes, H.; Moser, D.; Lenngenhager, R.; Brand, O. 1991: Thermal microtransducers by CMOS technology combined with micromachining. Microelectronic Engineering 15(1-4): 419-422
Scott, L.T.; Necula, A. 1997: Thermal migration of an ethynyl group from one benzene ring to another by reversible vinylidene CH insertion. Tetrahedron Letters 38(11): 1877-1880
Le Guillou, M.; Moncoffre, N.; Toulhoat, N.; Pipon, Y.; Ammar, M.; Rouzaud, J.; Deldicque, D. 2016: Thermal migration of deuterium implanted in graphite: Influence of free surface proximity and structure. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 371: 307-311
Merten, U.; Bokros, J.; Guggisberg, D.; Hatcher, A. 1963: Thermal migration of hydrogen in zirconium-uranium-hydrogen alloys. Journal of Nuclear Materials 10(3): 201-208
Asundi, V.K.; Joshi, M.C.; Deb, S.K.; Kulkarni, V.N.; Sood, D.K.; Sundararaman, M. 1980: Thermal migration of iron implanted in aluminium at high doses. Radiation Effects 49(1-3): 39-44
Tempel, A.; Mäuder, M.; Zehe, A.; Gröutzschel, R. 1988: Thermal mismatch biased rhombohedral structure of strained epitaxial Ca F2 films on Si(111). Physica Status Solidi (a) 109(2): 493-501
Zheleva, T.S.; Ashmawi, W.M.; Nam, O.; Davis, R.F. 1999: Thermal mismatch stress relaxation via lateral epitaxy in selectively grown Ga N structures. Applied Physics Letters 74(17): 2492-2494
Sarkar, K.; Sund, S.E.; Bose, D.; Yamanis, J. 1990: Thermal mismatch study in a ceramic to metal joint using the finite element method. Mathematical and Computer Modelling 14: 842-848
Georgi, G.W. 1970: Thermal mission analysis for the lunar module. Journal of Spacecraft and Rockets 7(5): 618-619
Tochio, D.; Fujimoto, N. 2015: Thermal mixing characteristics of helium gas in high-temperature gas-cooled reactor, (I) thermal mixing behavior of helium gas in HTTR. Journal of Nuclear Science and Technology 53(3): 425-431
Teh, A.L.; Chin, K.W.; Teh, E.K.; Chin, W.M.; Chia, C.M.; Foo, J.J. 2015: Thermal mixing enhancement of a free-cooling system with a fractal orifice plate. Chemical Engineering Research and Design 100: 57-71
Meyer, M.; Mendoza Zélis, L.; Sánchez, F.H.; Traverse, A. 1994: Thermal mixing of Al-Fe multilayers. Hyperfine Interactions 83(1): 327-331
Li, X.; Wu, X. 2013: Thermal mixing of the cross flow over tube bundles. International Journal of Heat and Mass Transfer 67: 352-361
Hayashi, N.; Morii, K.; Matsui, T.; Nakayama, Y. 1991: Thermal mixing of thin multilayered Pt/Mn/Sb films. Materials Science and Engineering: B10(3): 209-215
Ajarostaghi, S.S.M.; Delavar, M.A.; Poncet, S. 2019: Thermal mixing, cooling and entropy generation in a micromixer with a porous zone by the lattice Boltzmann method. Journal of Thermal Analysis and Calorimetry 140(3): 1321-1339
Vaskonen, K.; Eloranta, J.; Kiljunen, T.; Kunttu, H. 1999: Thermal mobility of atomic hydrogen in solid argon and krypton matrices. The Journal of Chemical Physics 110(4): 2122-2128
Ye, H.; Niebuhr, C.; Stever, R.; Gadow, K.; Camien, C. 2018: Thermal mock-up studies of the Belle Ii vertex detector. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 896: 82-89
Ghavami Sabouri, S.; Khorsandi, A.; Ebrahim-Zadeh, M. 2012: Thermal mode-switching of a passively Q-switched microchip Nd:YAG laser. Applied Physics B 108(2): 261-268
Paul, S.; Singh, R.; Yan, W. 2016: Thermal model for additive restoration of mold steels using crucible steel. Journal of Manufacturing Processes 24: 346-354
Avila, A.; Asomoza, R. 2000: Thermal model for breakdown in p-type hydrogenated amorphous silicon films with coplanar electrodes. Solid-State Electronics 44(9): 1647-1653
Sinha, S. 2015: Thermal model for nanosecond laser ablation of alumina. Ceramics International 41(5): 6596-6603
de Martini Fernandes, L.; Lopes, J.C.; Ribeiro, F.S.F.; Gallo, R.; Razuk, H.C.; de Angelo Sanchez, L.E.; de Aguiar, P.R.; de Mello, H.J.; Bianchi, E.C. 2019: Thermal model for surface grinding application. International Journal of Advanced Manufacturing Technology 104(5-8): 2783-2793
Pinotti, E.; Sassella, A.; Borghesi, A. 2001: Thermal model of Knudsen cells for organic molecular beam deposition. Journal of Vacuum Science-Technology A: Vacuum, Surfaces, and Films 19(3): 878-882
Narayanan, M.R.; Al-Nashash, H.; Pal, D.; Chandra, M. 2013: Thermal model of MOSFET with SELBOX structure. Journal of Computational Electronics 12(4): 803-811
Dhingra, K.; Bryant, H. 1983: Thermal model of a cylindrically symmetric solar pond. Solar Energy 30(6): 589-595
Zhang, S.; Wang, X. 2013: Thermal model of continuous wave end-pumped passively Q-switched laser. Optics Communications 295: 155-160
Tønder, K. 1976: Thermal model of effects of gas bubbles on the lubrication of parallel surfaces. Wear 40(1): 37-50
Mostafavi, S.A.; Joneidi, Z. 2022: Thermal model of precast concrete curing process: Minimizing energy consumption. Mathematics and Computers in Simulation 191: 82-94
Evelyne, T.; Annelore, B.; François, B.; Sébastien, P. 2018: Thermal model of successive dike injections and implications for the development of intraplate volcanoes. Lithos 322: 129-147
Bryan, J.L.; Silverman, T.J.; Deceglie, M.G.; Holman, Z.C. 2021: Thermal model to quantify the impact of sub-bandgap reflectance on operating temperature of fielded PV modules. Solar Energy 220: 246-250
Ukar, E.; Lamikiz, A.; López de Lacalle, L.; Martinez, S.; Liébana, F.; Tabernero, 2010: Thermal model with phase change for process parameter determination in laser surface processing. Physics Procedia 5: 395-403
Xing, H.; Zhao, H.; Zhang, Y.; Zhang, Q. 2012: Thermal modeling and analysis of a radiometer for thermal control coatings in situ measurement. Acta Astronautica 71: 99-108
Vaddina, K.R.; Rahmani, A.; Latif, K.; Liljeberg, P.; Plosila, J. 2012: Thermal modeling and analysis of advanced 3D stacked structures. Procedia Engineering 30: 248-257
Sekhon, M.; Sethi, V.P. 2018: Thermal modeling and analysis of novel twin-chamber community solar cooker as a replacement of biomass-based cooking. International Journal of Green Energy 16(2): 167-184
Kalbasi, R.; Alemrajabi, A.A.; Afrand, M. 2018: Thermal modeling and analysis of single and double effect solar stills: An experimental validation. Applied Thermal Engineering 129: 1455-1465
Velazquez-Salazar, A.; Berquez, L.; Marty-Dessus, D. 2018: Thermal modeling and calibration in (F)LIMM using an external bias field: Theory and experiment. IEEE Transactions on Dielectrics and Electrical Insulation 25(3): 783-790
Hejripour, F.; Binesh, F.; Hebel, M.; Aidun, D.K. 2019: Thermal modeling and characterization of wire arc additive manufactured duplex stainless steel. Journal of Materials Processing Technology 272: 58-71
Wu, R.; Hong, T.; Cheng, Q.; Zou, H.; Fan, Y.; Luo, X. 2019: Thermal modeling and comparative analysis of jet impingement liquid cooling for high power electronics. International Journal of Heat and Mass Transfer 137: 42-51
Mishra, R.; Garg, V.; Tiwari, G. 2015: Thermal modeling and development of characteristic equations of evacuated tubular collector (ETC). Solar Energy 116: 165-176
Dehghan, A.A.; Afshari, A.; Rahbar, N. 2015: Thermal modeling and exergetic analysis of a thermoelectric assisted solar still. Solar Energy 115: 277-288
Tomar, V.; Tiwari, G.; Bhatti, T.; Norton, B. 2018: Thermal modeling and experimental evaluation of five different photovoltaic modules integrated on prototype test cells with and without water flow. Energy Conversion and Management 165: 219-235
Mohanraj, R.; Elangovan, S. 2020: Thermal modeling and experimental investigation on the influences of the process parameters on warm incremental sheet metal forming of titanium grade 2 using electric heating technique. International Journal of Advanced Manufacturing Technology 110(1-2): 255-274
Misiopecki, C.; Bouquin, M.; Gustavsen, A.; Jelle, B.P. 2018: Thermal modeling and investigation of the most energy-efficient window position. Energy and Buildings 158: 1079-1086
Lin, J.; Zheng, H.; Zhu, Z.; David, H.; Zhang, Z. 2007: Thermal modeling and management of DRAM memory systems. ACM SIGARCH Computer Architecture News 35(2): 312-322
Guo, C.; Chen, Y. 2018: Thermal modeling and optimization of interrupted grinding. CIRP Annals 67(1): 321-324
Panchal, S.; Dincer, I.; Agelin-Chaab, M.; Fraser, R.; Fowler, M. 2016: Thermal modeling and validation of temperature distributions in a prismatic lithium-ion battery at different discharge rates and varying boundary conditions. Applied Thermal Engineering 96: 190-199
Axelsson, S. 1988: Thermal modeling for the estimation of energy losses from municipal heating networks using infrared thermography. IEEE Transactions on Geoscience and Remote Sensing 26(5): 686-692
Park, S.; Woo, S.; Kim, M.; Lee, K. 2016: Thermal modeling in an engine cooling system to control coolant flow for fuel consumption improvement. Heat and Mass Transfer 53(4): 1479-1489
Min, J.; Seim, P.; Störkle, D.; Thyssen, L.; Kuhlenkötter, B. 2016: Thermal modeling in electricity assisted incremental sheet forming. International Journal of Material Forming 10(5): 729-739
Redfield, R.C. 2010: Thermal modeling in mountain bike air shocks. Procedia Engineering 2(2): 2625-2630
Denlinger, E.R.; Jagdale, V.; Srinivasan, G.; El-Wardany, T.; Michaleris, P. 2016: Thermal modeling of Inconel 718 processed with powder bed fusion and experimental validation using in situ measurements. Additive Manufacturing 11: 7-15
Mathias, E.C.; Ahmad, R.A. 1994: Thermal modeling of Shuttle solid rocket motors on the launch pad. Journal of Spacecraft and Rockets 31(2): 237-242
Boutriaa, A.; Rahmani, A. 2017: Thermal modeling of a basin type solar still enhanced by a natural circulation loop. Computers-Chemical Engineering 101: 31-43
Khlissa, R.; Vivier, S.; Friedrich, G.; El Kadri Benkara, K.; Assaad, B. 2016: Thermal modeling of an asymmetrical totally enclosed permanent magnet integrated starter generator. Mathematics and Computers in Simulation 130: 32-47
Paradis, P.; Rousse, D.R.; Hallé, S.; Lamarche, L.; Quesada, G. 2015: Thermal modeling of evacuated tube solar air collectors. Solar Energy 115: 708-721
Darvazi, A.R.; Iranmanesh, M. 2014: Thermal modeling of friction stir welding of stainless steel 304L. International Journal of Advanced Manufacturing Technology 75(9-12): 1299-1307
Cao, W.; Zhao, C.; Wang, Y.; Dong, T.; Jiang, F. 2019: Thermal modeling of full-size-scale cylindrical battery pack cooled by channeled liquid flow. International Journal of Heat and Mass Transfer 138: 1178-1187
Kong, X.; Doré, G.; Calmels, F. 2019: Thermal modeling of heat balance through embankments in permafrost regions. Cold Regions Science and Technology 158: 117-127
Raj, S.A.; Chandrasekar, M. 1994: Thermal modeling of heat transfer. Journal of Thermophysics and Heat Transfer 8(3): 624-625
Trovò, A.; Saccardo, A.; Giomo, M.; Guarnieri, M. 2019: Thermal modeling of industrial-scale vanadium redox flow batteries in high-current operations. Journal of Power Sources 424: 204-214
Damay, N.; Forgez, C.; Bichat, M.; Friedrich, G. 2015: Thermal modeling of large prismatic Li Fe PO 4 /graphite battery. Coupled thermal and heat generation models for characterization and simulation. Journal of Power Sources 283: 37-45
Deshmukh, N.; Rajurkar, A.; Kolekar, O.; Mule, R.; Chinchanikar, S. 2021: Thermal modeling of laser surface micro-texturing: Investigation on effects of laser parameters on dimple-texture dimensions and aspect ratio. Materials Today: Proceedings 46: 8374-8380
Tangyunyong, P. 2003: Thermal modeling of localized laser heating in multi-level interconnects. Microelectronics Reliability 43(2): 297-305
Shaker, Y.O.; El-Hag, A.H.; Patel, U.; Jayaram, S.H. 2014: Thermal modeling of medium voltage cable terminations under square pulses. IEEE Transactions on Dielectrics and Electrical Insulation 21(3): 932-939
Yenchek, M.; Cole, G. 1997: Thermal modeling of portable power cables. IEEE Transactions on Industry Applications 33(1): 72-79
Fagundes, J.; Batista, A.; Viarouge, P. 1997: Thermal modeling of pot core magnetic components used in high frequency static converters. IEEE Transactions on Magnetics 33(2): 1710-1713
Souza, L.; Lemos, A.; Caminhas, W.; Boaventura, W. 2012: Thermal modeling of power transformers using evolving fuzzy systems. Engineering Applications of Artificial Intelligence 25(5): 980-988
Gilbert, K.; Handler, W.; Chronik, B. 2005: Thermal modeling of resistive magnets for field-cycled MRi. Concepts in Magnetic Resonance Part B: Magnetic Resonance Engineering 26B(1): 56-66
Nadda, R.; Nirala, C.K. 2020: Thermal modeling of single discharge in prospect of tool wear compensation in μEDM. International Journal of Advanced Manufacturing Technology 107(11-12): 4573-4595
Kao, T.; Cho, S.; Pai, D. 1982: Thermal modeling of steam generator tubing under CHF-induced temperature oscillations. International Journal of Heat and Mass Transfer 25(6): 781-790
Zhang, Y.; Stracener, D.; Alton, G. 2005: Thermal modeling of the HRIBF targets. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 241(1-4): 996-1000
Faircloth, D.C.; Thomason, J.W.G.; Lau, W.; Yang, S. 2004: Thermal modeling of the ISIS H− ion source. Review of Scientific Instruments 75(5): 1738-1740
Gutscher, M.; Klingelhoefer, F.; Theunissen, T.; Spakman, W.; Berthet, T.; Wang, T.; Lee, C. 2016: Thermal modeling of the SW Ryukyu forearc (Taiwan): Implications for the seismogenic zone and the age of the subducting Philippine Sea Plate (Huatung Basin). Tectonophysics 692: 131-142
Chato, J.C.; Shitzer, A. 1971: Thermal modeling of the human body - Further solutions of the steady-state heat equation. AIAA Journal 9(5): 865-869
Mahaney, H.V. 1993: Thermal modeling of the infrared reflow process for Solder Ball Connect (SBC). IBM Journal of Research and Development 37(5): 609-620
Salonitis, K.; Stournaras, A.; Stavropoulos, P.; Chryssolouris, G. 2009: Thermal modeling of the material removal rate and surface roughness for die-sinking EDM. International Journal of Advanced Manufacturing Technology 40(3-4): 316-323
Akbari, M.; Bahman, A.; Reigosa, P.; Iannuzzo, F.; Bina, M. 2018: Thermal modeling of wire-bonded power modules considering non-uniform temperature and electric current interactions. Microelectronics Reliability 88-90: 1135-1140
Langlois, P.Y.; Dolabdjian, C.P.; Robbes, D.P.; Bloyet, D.; Hamet, J.F.; Mossang, E.; Thomas, O. 1994: Thermal modelization and experiments on the current of superconducting microbridges dependence to light in the 10–90K range. Physica B: Condensed Matter 194-196: 2125-2126
Venkataraman, V. 2019: Thermal modelling and coupling of a heat pipe integrated desorber with a Solid Oxide Fuel Cell. Applied Thermal Engineering 147: 943-961
Babus'Haq, R.; Probert, D. 1992: Thermal modelling and design of electronic systems and devices. Applied Energy 42(3): 220-222
Medhi, T.; Saha Roy, B.; Debbarma, S.; Saha, S. 2015: Thermal modelling and effect of process parameters in friction stir welding. Materials Today: Proceedings 2(4-5): 3178-3187
Afzali Gorouh, H.; Salmanzadeh, M.; Nasseriyan, P.; Hayati, A.; Cabral, D.; Gomes, J.; Karlsson, B. 2022: Thermal modelling and experimental evaluation of a novel concentrating photovoltaic thermal collector (CPVT) with parabolic concentrator. Renewable Energy 181: 535-553
Wu, T.; Lei, C. 2016: Thermal modelling and experimental validation of a semi-transparent water wall system for Sydney climate. Solar Energy 136: 533-546
Rajput, P.; Tiwari, G.; Sastry, O. 2016: Thermal modelling and experimental validation of hot spot in crystalline silicon photovoltaic modules for real outdoor condition. Solar Energy 139: 569-580
Kiran Naik, B.; Muthukumar, P.; Bhattacharyya, C. 2018: Thermal modelling and parametric investigations on coupled heat and mass transfer processes occurred in a packed tower. Heat and Mass Transfer 55(3): 627-644
Strąkowska, M.; Strąkowski, R.; Strzelecki, M.; De Mey, G.; Więcek, B. 2018: Thermal modelling and screening method for skin pathologies using active thermography. Biocybernetics and Biomedical Engineering 38(3): 602-610
Eme, A.; Glises, R.; Chamagne, D.; Kauffmann, J.; Chalon, F.; Péra, T. 2006: Thermal modelling for electrical machines fed with low voltage. Mathematics and Computers in Simulation 71(4-6): 440-445
Meraj, M.; Azhar, M.; Khan, M.; Salik Anjum, M.S.; Sahil Faiz Ahmad, M.; Ab Rasheed, M.F.; Iqbal Ahmed, S.I.; Maqbul Alam, M.N. 2021: Thermal modelling of PVT-CPC integrated vapour absorption refrigeration system. Materials Today: Proceedings 38: 391-396
Carmona, M.; Palacio, M. 2019: Thermal modelling of a flat plate solar collector with latent heat storage validated with experimental data in outdoor conditions. Solar Energy 177: 620-633
Lin, Q.; Yixiong, T.; Xuezhang, M.; Ruizhen, Q.; Jiqiang, W.; Yuegen, C.; Heng, Z. 1993: Thermal modelling of a high power Li/SOC12 cell with parallel plates. Journal of Power Sources 43(1-3): 309-315
Corley, B.; Carroll, J.; McDonald, A. 2019: Thermal modelling of a small wind turbine gearbox for condition monitoring. The Journal of Engineering 18: 5335-5339
Wang, X.; Kendrick, C.; Ogden, R.; Baiche, B.; Walliman, N. 2012: Thermal modelling of an industrial building with solar reflective coatings on external surfaces: case studies in China and Australia. Journal of Building Performance Simulation 5(3): 199-207
Jones, C.; Capper, P.; Gosney, J. 1982: Thermal modelling of bridgman crystal growth. Journal of Crystal Growth 56(3): 581-590
Akbar, F.; Arsalan, M. 2021: Thermal modelling of cutting tool temperatures and heat partition in orthogonal machining of high-strength alloy steel. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture 235(8): 1309-1326
Schmidt, H.; Hattel, J. 2008: Thermal modelling of friction stir welding. Scripta Materialia 58(5): 332-337
Zeinalzadeh, A.; Moussavi-Harami, R.; Mahboubi, A.; Kassaie-Najafi, M.; Rezaee, R. 2018: Thermal modelling of gas generation and retention in the Jurassic organic-rich intervals in the Darquain field, Abadan Plain, SW Iran. Journal of Petroleum Exploration and Production Technology 9(2): 971-987
Bezotosnyi, V V.; Krokhin, O N.; Oleshchenko, V A.; Pevtsov, V F.; Popov, Y. M.; Cheshev, E A. 2014: Thermal modelling of high-power laser diodes mounted using various types of submounts. Quantum Electronics 44(10): 899-902
Janicki, M.; Napieralski, A.; Fedasyuk, D.; Petrov, D. 2000: Thermal modelling of hybrid circuits: simulation method comparison. Microelectronics Reliability 40(3): 541-546
Katiyar, N.; Balasubramanian, K. 2014: Thermal modelling of hybrid composites of nano cenosphere and polycarbonate for a thermal protection system. RSC Adv. 4(88): 47529-47535
Bognár, G.; Takács, G.; Pohl, L.; Szabó, P.G. 2017: Thermal modelling of integrated microscale heatsink structures. Microsystem Technologies 24(1): 433-444
Bartoli, F.; Esterowitz, L.; Kruer, M.; Allen, R. 1975: Thermal modelling of laser damage in 8–14‐μm Hg Cd Te photoconductive and Pb Sn Te photovoltaic detectors. Journal of Applied Physics 46(10): 4519-4525
Jedrasiak, P.; Shercliff, H.; McAndrew, A.; Colegrove, P. 2018: Thermal modelling of linear friction welding. Materials-Design 156: 362-369
Sievers, M.; Sievers, U.; Mao, S.S. 2010: Thermal modelling of new Li-ion cell design modifications. Forschung im Ingenieurwesen 74(4): 215-231
Tiwari, S.; Bhatti, J.; Tiwari, G.; Al-Helal, I. 2016: Thermal modelling of photovoltaic thermal (PVT) integrated greenhouse system for biogas heating. Solar Energy 136: 639-649
Soldner, D.; Mergheim, J. 2019: Thermal modelling of selective beam melting processes using heterogeneous time step sizes. Computers-Mathematics with Applications 78(7): 2183-2196
Dimri, N.; Tiwari, A.; Tiwari, G. 2017: Thermal modelling of semitransparent photovoltaic thermal (PVT) with thermoelectric cooler (TEC) collector. Energy Conversion and Management 146: 68-77
Fürst, Y.; Brandt, S.; Kriegel, M. 2020: Thermal modelling of three-way mixing valves using Bézier curves for parameter estimation applications. Journal of Process Control 90: 56-62
Hu, X.; Shi, X.; Sierks, H.; Blum, J.; Oberst, J.; Fulle, M.; Kührt, E.; Güttler, C.; Gundlach, B.; Keller, H.U.; Mottola, S.; Pajola, M.; Barbieri, C.; Lamy, P.L.; Rodrigo, R.; Koschny, D.; Rickman, H.; Agarwal, J.; A'Hearn, M.F.; Barucci, M.A.; Bertaux, J.; Bertini, I.; Boudreault, S.; Büttner, I.; Cremonese, G.; Da Deppo, V.; Davidsson, B.; Debei, S.; De Cecco, M.; Deller, J.; Fornasier, S.; Groussin, O.; Gutiérrez, P.J.; Gutiérrez-Marqués, P.; Hall, I.; Hofmann, M.; Hviid, S.F.; Ip, W.; Jorda, L.; Knollenberg, J.; Kovacs, .; Kramm, J.R.; Küppers, M.; Lara, L.M.; Lazzarin, M.; López-Moreno, J.J.; Marzari, F.; Naletto, G.; Oklay, N.; Richards, M.L.; Ripken, J.; Thomas, N.; Tubiana, C.; Vincent, J. 2017: Thermal modelling of water activity on comet 67P/Churyumov-Gerasimenko with global dust mantle and plural dust-to-ice ratio. Monthly Notices of the Royal Astronomical Society 469(Suppl_2): S295-S311
Kruer, M.; Esterowitz, L.; Allen, R.; Bartoli, F. 1976: Thermal models for laser damage in in Sb photovoltaic and photoconductive detectors. Infrared Physics 16(3): 375-384
Daniels, K.; Bastow, I.; Keir, D.; Sparks, R.; Menand, T. 2014: Thermal models of dyke intrusion during development of continent–ocean transition. Earth and Planetary Science Letters 385: 145-153
Landini, M.; Monsignori Fossi, B.C.; Pallavicini, R. 1975: Thermal models of flaring region based on observations by the SOLRAD 10 satellite. Solar Physics 44(1): 101-116
Clark Jr., A. 1979: Thermal models of sunspots. Solar Physics 62(2): 305-330
Köster, L.; Gerth, H.; Haase, H. 2000: Thermal modes and their application to turbogenerator rotors. Electrical Engineering (Archiv fur Elektrotechnik) 82(3-4): 135-144
Filimonov, V.Y.; Koshelev, K.B.; Sytnikov, A.A. 2017: Thermal modes of heterogeneous exothermic reactions. Solid-phase interaction. Combustion and Flame 185: 93-104
Marcon, B.; Tondi, G.; Procino, L.; Goli, G. 2021: Thermal modification kinetics and chemistry of poplar wood in dry and saturated steam media. Holzforschung 75(8): 721-730
Wang, W.; Zhu, Y.; Cao, J.; Guo, X. 2015: Thermal modification of Southern pine combined with wax emulsion preimpregnation: effect on hydrophobicity and dimensional stability. Holzforschung 69(4): 405-413
Suzuki, K.; Gubler, P.; Morita, K.; Oka, M. 2013: Thermal modification of bottomonium spectra from QCD sum rules with the maximum entropy method. Nuclear Physics A 897: 28-41
Ajala, E.O.; Ajala, M.A.; Odetoye, T.E.; Aderibigbe, F.A.; Osanyinpeju, H.O.; Ayanshola, M.A. 2020: Thermal modification of chicken eggshell as heterogeneous catalyst for palm kernel biodiesel production in an optimization process. Biomass Conversion and Biorefinery 11(6): 2599-2615
Kowalska, E.; Byszewski, P.; Klusek, Z.; Popławska, M.; Radomska, J. 2003: Thermal modification of ferrocene derivative adducts to c60for SMT observations. Journal of Thermal Analysis and Calorimetry 74(2): 459-463
Kuszewski, K. 1988: Thermal modification of properties of thermosetting materials. Polimery 33(07-08): 267-269
Vornanen, M.; Haverinen, J.; Hassinen, M. 2007: Thermal modification of the delayed rectifier potassium current of the fish heart. Comparative Biochemistry and Physiology Part A: Molecular-Integrative Physiology 146(4): S167-S168
Collins, C.; Carroll, J.; Lee, F.; Waller, R.; Cunningham, A. 1976: Thermal modification of the kinetic sequence pumping the helium-nitrogen charge transfer laser. Optics Communications 18(1): 179-180
Collins, C.B.; Carroll, J.M.; Lee, F.W.; Cunningham, A.J. 1976: Thermal modification of the kinetic sequence pumping the helium‐nitrogen charge‐transfer laser. Applied Physics Letters 28(9): 535-537
Doll, K.M.; Hwang, H. 2013: Thermal modification of vegetable oils. Lipid Technology 25(4): 83-85
Hill, C.; Altgen, M.; Rautkari, L. 2021: Thermal modification of wood- a review: chemical changes and hygroscopicity. Journal of Materials Science 56(11): 6581-6614
Rahaman, S.; Nath, B.; Mondal, C.K. 2017: Thermal modulation in Zeno and anti-Zeno effects on quantum measurement. Molecular Physics 115(23): 2961-2969
Lillywhite, H.B. 1971: Thermal modulation of cutaneous mucus discharge as a determinant of evaporative water loss in the frog, Rana catesbeiana. Zeitschrift fr Vergleichende Physiologie 73(1): 84-104
Kao, Y.J.; Farley, T. 1978: Thermal modulation of pyruvate substrate inhibition in the B42′ and B42″ liver lactate dehydrogenases of rainbow trout, Salmo gairdneri. Comparative Biochemistry and Physiology Part B: Comparative Biochemistry 60(2): 153-155
Wang, C.; Wang, Z.; Zhang, D.; Zhu, D. 2006: Thermal modulation of the monomer/excimer fluorescence for bispyrene molecules through the gel–solution transition of an organogel: a thermo-driven molecular fluorescence switch. Chemical Physics Letters 428(1-3): 130-133
Hipps, K.W.; Francis, A.H. 1979: Thermal modulation spectroscopy applied to inorganic compounds with near degenerate excited states. The Journal of Physical Chemistry 83(14): 1879-1884
Tada, K.; Tsou, K.; Zemel, J. 1974: Thermal modulation spectroscopy of biological films. Thin Solid Films 22(1): 45-55
Singh, M.K.; Mahapatra, S.; Atreya, S.; Givoni, B. 2010: Thermal monitoring and indoor temperature modeling in vernacular buildings of North-East India. Energy and Buildings 42(10): 1610-1618
Emamian, A.; Farshidianfar, M.H.; Khajepour, A. 2017: Thermal monitoring of microstructure and carbide morphology in direct metal deposition of Fe-Ti-C metal matrix composites. Journal of Alloys and Compounds 710: 20-28
Varlamov, S. 2018: Thermal monitoring of railway subgrade in a region of ice-rich permafrost, Yakutia, Russia. Cold Regions Science and Technology 155: 184-192
Zakšek, K.; Pick, L.; Shirzaei, M.; Hort, M. 2015: Thermal monitoring of volcanic effusive activity: the uncertainties and outlier detection. Geological Society, London, Special Publications 426(1): 93-113
Kondo, S.; Kobayashi, A.; Nagata, H. 1997: Thermal monitoring system during drilling with a high speed drill in skull base surgery. Clinical Neurology and Neurosurgery 99: S155-S156
Phoenix, A. A.; Borggaard, J.; Tarazaga, P. A. 2017: Thermal morphing anisogrid smart space structures part 2: Ranking of geometric parameter importance, trust region optimization, and performance evaluation. Journal of Vibration and Control 24(13): 2873-2893
Filippini, G. 1990: Thermal motion analysis in [5]-, [6]- and [7]-circulene crystals: a harmonic lattice-dynamical calculation. Acta Crystallographica Section B Structural Science 46(5): 643-645
Gramaccioli, C.M.; Filippini, G. 1985: Thermal motion analysis ino-terphenyl: a lattice-dynamical approach. Acta Crystallographica Section A Foundations of Crystallography 41(4): 361-365
Logan, J.; Hough, J.; Thomson, R. 1996: Thermal motion associated with monolithic fused silica cradle suspensions for gravitational wave detectors. Physics Letters A 218(3-6): 181-189
Shokri, B.; Vazifehshenas, T. 2001: Thermal motion effect on the filamentation of a strongly collisional current-driven plasma. Physics of Plasmas 8(3): 788-790
Marchese, F.T.; Beveridge, D.L. 1986: Thermal motion from monte carlo simulations of aqueous ionic solutions. International Journal of Quantum Chemistry 29(4): 619-625
Nelmes, R.J.; Meyer, G.M.; Hutton, J. 1978: Thermal motion in Sr Ti O3at room temperature: Anharmonic or disordered?. Ferroelectrics 21(1): 461-462
Beutier, G.; Collins, S.P.; Nisbet, G.; Ovchinnikova, E.N.; Dmitrienko, V.E. 2012: Thermal motion induced resonant forbidden reflections in wurtzite Ga N. The European Physical Journal Special Topics 208(1): 53-66
Kay, M.I.; Cromer, D.T. 1970: Thermal motion of the sulfate group in sodium alum Na Al(SO4)2.12H2O. Acta Crystallographica Section B Structural Crystallography and Crystal Chemistry 26(9): 1349-1355
Lutz, H.D.; Saßmannshausen, M. 2000: Thermal motion of the univalent metal ions in KCr5S8-type chalcogenides, ternary chromium selenides M x Cr5Se8 (M  = Rb, Cs). Zeitschrift für Kristallographie - Crystalline Materials 215(11): 683-687
Sasaki, S.; Takiguchi, Y.; Kamata, M.; Uematsu, I. 1979: Thermal motion of α-helical molecules in highly crystalline poly(γ-methyl l-glutamate) films. Polymer 20(1): 71-75
Romeo, G. 2011: Thermal motions quantification of lysozyme in aqueous mixtures with different co-solvent: glycerol [C3H5(OH)3], trehalose [C12H22O11], sucrose [C12H22O11], and a chaotropic agent [CO(NH2)2] by osiris near-backscattering crystal analyser spectrometer. Applied Physics A 106(4): 893-900
Avdeyev, S.; Karnaukhov, V.; Kuznetsov, W.; Petrov, L.; Rodionov, V.; Zubkevich, A.; Oeschler, H.; Bochkarev, O.; Chulkov, L.; Kuzmin, E.; Budzanovski, A.; Karcz, W.; Janicki, M.; Norbeck, E.; Botvina, A.; Friedman, W.; Nörenberg, W.; Papp, G. 1998: Thermal multifragmentation in p + au interactions at 2.16, 3.6 and 8.1 Ge V incident energies. The European Physical Journal A 3(1): 75-83
Matsushita, A.; Nagamine, K. 1998: Thermal muonium emission from platinum group metals. Physics Letters A 244(1-3): 174-178
Friar, J.; Gibson, B.; Payne, G. 1990: Thermal n-d radiative capture. Physics Letters B 251(1): 11-16
Mohapatra, S.; Pant, U.; Moirangthem, R.S. 2020: Thermal nanoimprint lithography based plasmonic nanogratings for refractive index sensing of polar solvents. Materials Today: Proceedings 28: 215-217
Beghein, C.; Xing, Z.; Goes, S. 2018: Thermal nature and resolution of the lithosphere–asthenosphere boundary under the Pacific from surface waves. Geophysical Journal International 216(2): 1441-1465
Boone, N.; Zhu, C.; Smith, C.; Todd, I.; Willmott, J. 2018: Thermal near infrared monitoring system for electron beam melting with emissivity tracking. Additive Manufacturing 22: 601-605
Kawano, H. 1971: Thermal negative ion emission from binary cesium halide mixtures on a niobium surface. The Journal of Physical Chemistry 75(24): 3741-3745
Pathak, K.; Chandra, R.; Raychaudhuri, B. 1985: Thermal network analysis of a conditioned building: the effect of location of insulation. Energy Conversion and Management 25(1): 85-92
Zhou, C.; Qu, Z.; Hu, B.; Li, S. 2021: Thermal network model and experimental validation for a motorized spindle including thermal–mechanical coupling effect. International Journal of Advanced Manufacturing Technology 115(1-2): 487-501
Maloney, J.; Wang, T.; Chen, B.; Thorp, J. 1982: Thermal network predictions of the daily temperature fluctuations in a direct gain room. Solar Energy 29(3): 207-223
Menapace, S.L.M.; Voigt, A.F. 1970: Thermal neutron activation analysis for potassium, holmium and lanthanum in tungsten bronzes. Journal of Radioanalytical Chemistry 6(1): 219-226
Batra, R.J.; Garg, A.N. 1989: Thermal neutron activation analysis of Cu in its ores by using an241Am−Be neutron source. Journal of Radioanalytical and Nuclear Chemistry Articles 129(2): 335-342
Hirose, A.; Wada, H.; Kobayashi, K.; Ishii, D. 1979: Thermal neutron activation analysis of hafnium in zircaloy with a van de Graaff accelerator. Journal of Radioanalytical Chemistry 52(1): 111-116
Begaa, S.; Messaoudi, M. 2018: Thermal neutron activation analysis of some toxic and trace chemical element contents in Mentha pulegium L. Radiochimica Acta 106(9): 769-774
Stalnaker, N.D.; Kenna, B.T.; Kahn, M. 1973: Thermal neutron activation: Sample preparation utilizing graphite as a diluent. Journal of Radioanalytical Chemistry 14(2): 395-400
Mehboob, K.; Ahmed, R.; Ali, M.; Tabassam, U. 2013: Thermal neutron albedo measurements for multilithic reflectors. Annals of Nuclear Energy 62: 1-7
Lee, W.; Mahood, D.; Ryge, P.; Shea, P.; Gozani, T. 1995: Thermal neutron analysis (TNA) explosive detection based on electronic neutron generators. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 99(1-4): 739-742
Zeng, Z.; Gong, H.; Yue, Q.; Li, J. 2015: Thermal neutron background measurement in CJPL. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 804: 108-112
Wilson, W.M.; Thomas, G.E.; Jackson, H.E. 1975: Thermal neutron capture gamma rays from neutron capture in Ni59and Ni63. Physical Review C 11(4): 1477-1481
Selin, E.; Wallander, E. 1970: Thermal neutron capture gamma rays from the 26Mg(n, γ)27Mg reaction. Nuclear Physics A 150(2): 305-310
Michaelis, W. 1970: Thermal neutron capture in 151Eu. Nuclear Physics A 155(1): 21-32
Hardell, R.; Hasselgren, A. 1969: Thermal neutron capture in 19F. Nuclear Physics A 123(1): 215-224
Ishaq, A.F.M.; Robertson, A.; Prestwich, W.V.; Kennett, T.J. 1977: Thermal neutron capture in isotopes of nickel. Zeitschrift fr Physik A: Atoms and Nuclei 281(4): 365-372
Robertson, A.; Kennett, T.J.; Prestwich, W.V. 1978: Thermal neutron capture in50V. Zeitschrift fr Physik A Atoms and Nuclei 284(4): 407-411
Gelletly, W.; Kane, W.R.; Casten, R.F. 1976: Thermal neutron capture on Ce142. Physical Review C 13(4): 1434-1445
Islam, M.A.; Kennett, T.J.; Prestwich, W.V. 1991: Thermal neutron capture γ-ray spectrum of molybdenum and ruthenium. Canadian Journal of Physics 69(6): 658-664
Harder, A.; Michaelsen, S.; Lieb, K.P.; Williams, A.P. 1993: Thermal neutron capture?-ray spectroscopy of59Ni and61Ni. Zeitschrift fr Physik A Hadrons and Nuclei 345(2): 143-153
Kikuchi, C. 1971: Thermal neutron damage in Cd S and Cd Te. Radiation Effects 8(3-4): 249-253
Mandić, I.; Cindro, V.; Kramberger, G.; Krištof, E.; Mikuž, M.; Vrtačnik, D. 2004: Thermal neutron damage in DMILL bipolar transistors. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 518(1-2): 474-476
Ait-Boubker, S.; Avenier, M.; Bagieu, G.; Cavaignac, J.; Collot, J.; Favier, J.; Kajfasz, E.; Koang, D.; Stutz, A.; Vignon, B. 1989: Thermal neutron detection and identification in a large volume with a new lithium-6 loaded liquid scintillator. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 277(2-3): 461-466
Schieber, M.; Mojaev, E.; Roth, M.; Zuck, A.; Khakhan, O.; Fleider, A. 2009: Thermal neutron detection at outer electrode surfaces of composite polycrystalline B, BN, B4C and Li F through air ionization. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 607(3): 634-639
Gordon, A.M.P.L.; Muccillo, R. 1979: Thermal neutron detection by activation of Ca SO4:Dy + KBr thermoluminescent phosphors. The International Journal of Applied Radiation and Isotopes 30(9): 571-573
Fiserova, L.; Janda, J. 2019: Thermal neutron detection using lanthanide oxybromides. Radiation Measurements 124: 116-121
de Souza, E.; Geraldo, L.; Pugliesi, R.; Crestana, S. 1995: Thermal neutron detection using pyroelectric ceramics together with boron converters. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 365(2-3): 427-432
Iwanowska, J.; Swiderski, L.; Moszynski, M.; Yanagida, T.; Yokota, Y.; Yoshikawa, A.; Fukuda, K.; Kawaguchi, N.; Ishizu, S. 2011: Thermal neutron detection with Ce3+ doped Li Ca Al F6 single crystals. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 652(1): 319-322
Arnaldi, R.; Chiavassa, E.; Colla, A.; Cortese, P.; Dellacasa, G.; De Marco, N.; Ferretti, A.; Gagliardi, M.; Gallio, M.; Gemme, R.; Musso, A.; Oppedisano, C.; Piccotti, A.; Poggio, F.; Scomparin, E.; Travaglia, G.; Vercellin, E.; Yermia, F. 2006: Thermal neutron detection with Resistive Plate Chambers via the 10B(n,α)7Li reaction. Nuclear Physics B - Proceedings Supplements 158: 177-181
McGregor, D.; Lindsay, J.; Olsen, R. 1996: Thermal neutron detection with cadmium1−x zincx telluride semiconductor detectors. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 381(2-3): 498-501
McGregor, D.; Unruh, T.; McNeil, W. 2008: Thermal neutron detection with pyrolytic boron nitride. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 591(3): 530-533
Engels, R.; Reinartz, R.; Schelten, J.; Czirr, B. 2000: Thermal neutron detection with the lithium borate scintillator. IEEE Transactions on Nuclear Science 47(3): 948-951
Pérez, M.; Blostein, J.J.; Bessia, F.A.; Tartaglione, A.; Sidelnik, I.; Haro, M.S.; Suárez, S.; Gimenez, M.L.; Berisso, M.G.; Lipovetzky, J. 2018: Thermal neutron detector based on COTS CMOS imagers and a conversion layer containing Gadolinium. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 893: 157-163
Ryzhikov, V.; Nagornaya, L.; Volkov, V.; Chernikov, V.; Zelenskaya, O. 2002: Thermal neutron detectors based on complex oxide crystals. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 486(1-2): 156-159
Mildenberger, F.; Mauerhofer, E. 2015: Thermal neutron die-away times in large samples irradiated with a pulsed 14 Me V neutron source. Journal of Radioanalytical and Nuclear Chemistry 307(1): 661-667
Abtahi, S.M.; Aghamiri, S.M.; Khalafi, H.; Zahmatkesh, M. 2013: Thermal neutron dose evaluation using MAGICA polymer gel dosimeter. IFMBE Proceedings: 1157-1159
Green, P.; Hurford, A. 1984: Thermal neutron dosimetry for fission track dating. Nuclear Tracks and Radiation Measurements (1982) 9(3-4): 231-241
Mohan, P.; Mohan, R.; Ahmed, F.; Kothari, L S. 1983: Thermal neutron extrapolation distances for slabs of beryllium and water. Journal of Physics D: Applied Physics 16(5): 715-722
Nasu, S.; Uchida, K.; Tanifuji, T.; Takeshita, H.; Isshiki, M.; Miyauchi, T.; Tanuma, K.; Sasajima, F. 1980: Thermal neutron flux distribution inside and outside Li2O pellets. Journal of Nuclear Materials 88(2-3): 193-198
Lee, C.; Zhou, X.; Harmon, J.; Bartholomay, R.; Harker, Y.; Kudchadker, R. 1999: Thermal neutron flux mapping in a head phantom. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 422(1-3): 106-110
Fisyak, Y.; Tsai, O.; Videbæk, F.; Xu, Z. 2014: Thermal neutron flux measurements in the STAR experimental hall. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 756: 68-72
Arutunian, S.; Bergoz, J.; Chung, M.; Harutyunyan, G.; Lazareva, E. 2015: Thermal neutron flux monitors based on vibrating wire. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 797: 37-43
Dangendorf, V.; Demian, A.; Friedrich, H.; Wagner, V.; Akkerman, A.; Breskin, A.; Chechik, R.; Gibrekhterman, A. 1994: Thermal neutron imaging detectors combining novel composite foil convertors and gaseous electron multipiers. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 350(3): 503-510
Winch, N.; Edgar, A.; Bartle, C. 2014: Thermal neutron imaging with Cs Br storage phosphors. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 763: 394-398
Kawaguchi, N.; Yanagida, T.; Fujimoto, Y.; Yokota, Y.; Kamada, K.; Fukuda, K.; Suyama, T.; Watanabe, K.; Yamazaki, A.; Chani, V.; Yoshikawa, A. 2011: Thermal neutron imaging with rare-earth-ion-doped Li Ca Al F6 scintillators and a sealed 252Cf source. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 652(1): 351-354
Bieber, R.; Wagemans, C.; Goeminne, G.; Wagemans, J.; Denecke, B.; Loiselet, M.; Gaelens, M.; Geltenbort, P.; Oberhummer, H. 1999: Thermal neutron induced (n,p) and (n,α) reactions on 37Ar. Nuclear Physics A 647(1-2): 3-11
Çelik, C.; Ünlü, K.; Ramakrishnan, K.; Rajaraman, R.; Narayanan, V.; Irwin, M.J.; Xie, Y. 2008: Thermal neutron induced soft error rate measurement in semiconductor memories and circuits. Journal of Radioanalytical and Nuclear Chemistry 278(2): 509-512
Kraft, A.; Heckner, K.-. 1993: Thermal neutron irradiation induced defects in n-Ga as and their annihilation by annealing processes. Journal of Radioanalytical and Nuclear Chemistry Articles 174(1): 167-175
Habibi, S.; Gupta, A.; Principi, G. 1992: Thermal neutron irradiation of Fe−Si−B glasses. Hyperfine Interactions 69(1-4): 623-626
Crow, M.; Jeng, U.; Nunes, A.; Malik, S.; Lin, D.; Bai, S.; Tehan, T.; Jacob, N.; Johnson, D.; Simoneau, W.; DiMeglio, A. 1995: Thermal neutron measurements of the Rhode Island Nuclear Science Center reactor after conversion to a compact low enriched uranium core. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 365(2-3): 433-445
Asmone, A.; Bertino, M.; Bini, C.; De Zorzi, G.; Diambrini Palazzi, G.; Di Cosimo, G.; Di Domenico, A.; Garufi, F.; Gauzzi, P.; Zanello, D.; Festinesi, A. 1994: Thermal neutron radiation damage on light yield and attenuation length of scintillating fibres. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 338(2-3): 398-403
Nelson, K.A.; Bellinger, S.L.; Edwards, N.S.; Montag, B.W.; Schmidt, A.J.; Wayant, C.; McGregor, D.S. 2014: Thermal neutron response and theoretical comparison of Li F coated aluminized Mylar. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 762: 130-134
Gauld, I.; Harvey, J.; Kennett, T.; Prestwich, W. 1986: Thermal neutron response of the Li2B4O7:Cu TL dosimeter. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 251(2): 380-385
Matsumoto, T. 1991: Thermal neutron response of thermoluminescence dosimeters for application to biomedical dosimetry. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 301(3): 552-557
Cuello, G.; Granada, J. 1997: Thermal neutron scattering by debye solids: a synthetic scattering function. Annals of Nuclear Energy 24(10): 763-783
Brostow, W. 1975: Thermal neutron scattering by liquid argon and the intermolecular potential. Chemical Physics Letters 35(3): 387-390
Will, G. 1972: Thermal neutron scattering by magnetic interaction. Annales de Physique 14(7): 371-405
Cuello, G.; Dawidowski, J.; Granada, J. 1997: Thermal neutron scattering by solids: Development and applications of a synthetic scattering law. Physica B: Condensed Matter 234-236: 1114-1116
Kutner, R.; Sosnowska, I. 1977: Thermal neutron scattering from a hydrogen-metal system in terms of a general multi-sublattice jump diffusion model- Ii. Journal of Physics and Chemistry of Solids 38(7): 747-750
Kutner, R.; Sosnowska, I. 1977: Thermal neutron scattering from a hydrogen-metal system in terms of a general multi-sublattice jump diffusion model- i. Journal of Physics and Chemistry of Solids 38(7): 741-746
Cantargi, F.; Granada, J.; Mayer, R. 2015: Thermal neutron scattering kernels for sapphire and silicon single crystals. Annals of Nuclear Energy 80: 43-46
Al-Qasir, I.; Gillette, V.; Qteish, A. 2019: Thermal neutron scattering kernels for uranium mono-nitride: a potential advanced tolerant fuel candidate for light water reactors. Annals of Nuclear Energy 127: 68-78
Koester, L.; Knopf, K.; Waschkowski, W. 1979: Thermal neutron scattering parameters for light nuclei (A=12 to 27). Zeitschrift fr Physik A Atoms and Nuclei 292(1): 95-103
Wang, L.; Cao, L.; Wu, H.; Kong, L.; Tang, Y. 2020: Thermal neutron scattering properties of Bismuth crystal filter. Journal of Nuclear Science and Technology 58(6): 704-713
Kim, H.; Rhee, J.; Jamil, M.; Ahmad, F.; Jeon, Y. 2015: Thermal neutron simulation response of GEM-based detectors with the FLUKA-MC package. Measurement 60: 71-77
Niimura, N.; Hirai, M.; Ishida, A.; Aizawa, K.; Yamada, K.; Ueno, M. 1989: Thermal neutron small-angle scattering spectrometer (WIT) using a 2D converging slit and annular glass scintillator detectors at KENS. Physica B: Condensed Matter 156-157: 611-614
Yu, Z.; Liu, G.; Zhu, M.; Xu, Y.; Zhao, E. 2010: Thermal neutron stars including the hyperon-hyperon interactions. Nuclear Physics A 834(1-4): 97c-99c
Beynon, T D.; Moon, J R. 1972: Thermal neutron transport near a moderator discontinuity using the method of weighted residuals - I. Theory. Journal of Physics D: Applied Physics 5(5): 931-949
Beynon, T D.; Moon, J R. 1973: Thermal neutron transport near a moderator discontinuity using the method of weighted residuals: III. Temperature discontinuities in graphite and light water. Journal of Physics D: Applied Physics 6(8): 953-965
Barnes, C.E.; Kikuchi, C. 1970: Thermal neutron-induced recoil defects in P-type cadmium telluride. Radiation Effects 2(4): 243-248
Dębicki, Z.; Jędrzejczak, K.; Karczmarczyk, J.; Kasztelan, M.; Lewandowski, R.; Orzechowski, J.; Szabelski, J.; Szeptycka, M.; Tokarski, P. 2009: Thermal neutrons at Gran Sasso. Nuclear Physics B - Proceedings Supplements 196: 429-432
Stenkin, Y. 2008: Thermal neutrons in EAS: a new dimension in EAS study. Nuclear Physics B - Proceedings Supplements 175-176: 326-329
Oliveira, D.; Blanchard, S.; DeBardeleben, N.; Fernandes dos Santos, F.; Piscoya Dávila, G.; Navaux, P.; Favalli, A.; Schappert, O.; Wender, S.; Cazzaniga, C.; Frost, C.; Rech, P. 2020: Thermal neutrons: a possible threat for supercomputer reliability. The Journal of Supercomputing 77(2): 1612-1634
Calatayud, J.; Hortal, J.; Noriega, J.A.; Arcones, .; Espinoza, V.R.; Guil, N.; Lobo, J.M. 2021: Thermal niche dimensionality could limit species' responses to temperature changes: Insights from dung beetles. Journal of Biogeography 48(12): 3072-3084
Scridel, D.; Bogliani, G.; Pedrini, P.; Iemma, A.; von Hardenberg, A.; Brambilla, M. 2017: Thermal niche predicts recent changes in range size for bird species. Climate Research 73(3): 207-216
Cuesta, F.; Tovar, C.; Llambí, L.D.; Gosling, W.D.; Halloy, S.; Carilla, J.; Muriel, P.; Meneses, R.I.; Beck, S.; Ulloa Ulloa, C.; Yager, K.; Aguirre, N.; Viñas, P.; Jácome, J.; Suárez‐Duque, D.; Buytaert, W.; Pauli, H. 2019: Thermal niche traits of high alpine plant species and communities across the tropical Andes and their vulnerability to global warming. Journal of Biogeography 47(2): 408-420
Rivera‐Ordonez, J.M.; Justin Nowakowski, A.; Manansala, A.; Thompson, M.E.; Todd, B.D. 2019: Thermal niche variation among individuals of the poison frog, Oophaga pumilio , in forest and converted habitats. Biotropica 51(5): 747-756
Morley, S.; Peck, L.; Tan, K.; Day, R.; Poertner, H. 2007: Thermal niche, aerobic scope and temperature sensitivity: a latitudinal comparison. Comparative Biochemistry and Physiology Part A: Molecular-Integrative Physiology 146(4): S209-S210
Mogi, T.K.; Thompson, M.O.; Gossmann, H.; Poate, J.M.; Luftman, H.S. 1996: Thermal nitridation enhanced diffusion of Sb and Si(100) doping superlattices. Applied Physics Letters 69(9): 1273-1275
Moslehi, M.; Saraswat, K. 1985: Thermal nitridation of Si and Si O2for VLSi. IEEE Transactions on Electron Devices 32(2): 106-123
Habraken, F.H.P.M.; Kuiper, A.E.T.; Tamminga, Y.; Theeten, J.B. 1982: Thermal nitridation of silicon dioxide films. Journal of Applied Physics 53(10): 6996-7002
Jintsugawa, O.; Sakuraba, M.; Matsuura, T.; Murota, J. 2002: Thermal nitridation of ultrathin Si O2 on Si by NH3. Surface and Interface Analysis 34(1): 456-459
Yang, X.; Li, C.; Yang, B.; Wang, W.; Qian, Y. 2004: Thermal nitridation synthesis of MN (M=Ti, V and Cr) nanocrystals from metals and NH4Cl. Materials Research Bulletin 39(7-8): 957-962
Rowan, S.; Hough, J.; Crooks, D. 2005: Thermal noise and material issues for gravitational wave detectors. Physics Letters A 347(1-3): 25-32
Pérez-Cárdenas, F.C. 2009: Thermal noise and the emergence of the arrow of time: a simple model. American Journal of Physics 77(5): 451-457
Fritze, W.; Steurer, M. 1998: Thermal noise and the incessant vibration of the outer hair cells in the cochlea. Discrete Dynamics in Nature and Society 2(3): 161-165
Basano, L.; Ottonello, P. 1975: Thermal noise as a source of Poisson distributions. American Journal of Physics 43(5): 452-453
Klippel, F.; Huth, G. 1968: Thermal noise behavior of a thick depletion region avalanche photodetector. Proceedings of the IEEE 56(7): 1222-1223
Nicolet, M.; Golder, J. 1973: Thermal noise calculation of single-carrier space-charge-limited current in a non-insulating solid. Physica Status Solidi (a) 15(2): 565-572
Yamamoto, K.; Ando, M.; Kawabe, K.; Tsubono, K. 2002: Thermal noise caused by an inhomogeneous loss in the mirrors used in the gravitational wave detector. Physics Letters A 305(1-2): 18-25
Tugolukov, M.; Levin, Y.; Vyatchanin, S. 2018: Thermal noise computation in gravitational wave interferometers from first principles. Physics Letters A 382(33): 2181-2185
Cella, G. 2018: Thermal noise correlations and subtraction. Physics Letters A 382(33): 2269-2274
Gras, S.; Blair, D.; Ju, L. 2004: Thermal noise dependence on equatorial losses in the mirrors of an interferometric gravitational wave detector. Physics Letters A 333(1-2): 1-7
Almasi, G.; Feth, G. 1969: Thermal noise from long sense lines. IEEE Transactions on Magnetics 5(1): 64-70
Brunk, G.; Lbbig, H. 1981: Thermal noise generated by quantum phase relaxations in Josephson tunnel junctions. Journal of Low Temperature Physics 42(3-4): 179-185
Caughey, D. 1964: Thermal noise in Hall-effect twoports. IEEE Transactions on Electron Devices 11(9): 441-442
Tong, K.; Ma, B.; Yuen, H. 2004: Thermal noise in RF CMOS mixers. Solid-State Electronics 48(5): 759-763
Bonaldi, M.; Falferi, P.; Cerdonio, M.; Vinante, A.; Dolesi, R.; Vitale, S. 1999: Thermal noise in a high Q cryogenic resonator. Review of Scientific Instruments 70(3): 1851-1856
Nenonen, J.; Montonen, J.; Katila, T. 1996: Thermal noise in biomagnetic measurements. Review of Scientific Instruments 67(6): 2397-2405
Zijlstra, R.; Gisolf, A. 1972: Thermal noise in double injection diodes operating in the insulator regime. Solid-State Electronics 15(8): 877-881
Trofimenkoff, F. 1965: Thermal noise in field-effect transistors. Proceedings of the IEEE 53(9): 1236-1237
van der Ziel, A.; Wu, E. 1983: Thermal noise in high electron mobility transistors. Solid-State Electronics 26(5): 383-384
Berkowitz, S.J.; Skocpol, W.J.; Mankiewich, P.M.; Ono, R.H.; Missert, N.; Rosenthal, P.A.; Vale, L.R. 1994: Thermal noise in high‐temperature superconducting‐normal‐ superconducting step‐edge Josephson junctions. Journal of Applied Physics 76(2): 1337-1339
Harry, G. M.; Gretarsson, A. M.; Saulson, P. R.; Kittelberger, S. E.; Penn, S. D.; Startin, W. J.; Rowan, S.; Fejer, M. M.; Crooks, D R M.; Cagnoli, G.; Hough, J.; Nakagawa, N. 2002: Thermal noise in interferometric gravitational wave detectors due to dielectric optical coatings. Classical and Quantum Gravity 19(5): 897-917
Huang, C.; van der Ziel, A. 1975: Thermal noise in ion-implanted MOSFETs. Solid-State Electronics 18(6): 509-510
Bruncke, W.; van der Ziel, A. 1966: Thermal noise in junction-gate field-effect transistors. IEEE Transactions on Electron Devices ED-13(3): 323-329
Williams, D. 1996: Thermal noise in lossy waveguides. IEEE Transactions on Microwave Theory and Techniques 44(7): 1067-1073
Bondu, F.; Hello, P.; Vinet, J. 1998: Thermal noise in mirrors of interferometric gravitational wave antennas. Physics Letters A 246(3-4): 227-236
Dollfus, P.; Bournel, A.; Galdin-Retailleau, S.; Velázquez, J.E. 2007: Thermal noise in nanometric DG-MOSFET. Journal of Computational Electronics 5(4): 479-482
Nicolet, M. 1971: Thermal noise in single and double injection devices. Solid-State Electronics 14(5): 377-380
van der Ziel, A. 1966: Thermal noise in space-charge-limited diodes. Solid-State Electronics 9(9): 899-900
Liu, S. 1967: Thermal noise in space-charge-limited solid state diodes. Solid-State Electronics 10(3): 253-254
Klaassen, F. 1968: Thermal noise in space-charge-limited solid-state diodes. Solid-State Electronics 11(3): 377-378
Shumka, A. 1970: Thermal noise in space-charge-limited solid-state diodes. Solid-State Electronics 13(6): 751-754
Shumka, A. 1971: Thermal noise in space-charge-limited solid-state diodes with field-dependent mobility and hot carriers. Solid-State Electronics 14(5): 367-369
Sharma, Y.K. 1974: Thermal noise in the diode with traps lying below the Fermi level. Physica Status Solidi (a) 23(2): K195-K198
DeMassa, T.A.; Iyer, S.R. 1975: Thermal noise in the linear graded channel junction FET. Solid-State Electronics 18(11): 933-935
Sharma, Y. 1974: Thermal noise in the trap free insulated diode with thermal free carriers. Solid-State Electronics 17(7): 762-763
Klein, M.; Mukherjee, A. 1982: Thermal noise induced switching of Josephson logic devices. Applied Physics Letters 40(8): 744-747
Pathan, A.; Liscidini, A. 2016: Thermal noise limit for time‐domain analogue signal processing in CMOS technologies. Electronics Letters 52(18): 1567-1569
Luo, J.; Shao, C.; Tian, Y.; Wang, D. 2013: Thermal noise limit in measuring the gravitational constant G using the angular acceleration method and the dynamic deflection method. Physics Letters A 377(21-22): 1397-1401
Amico, P.; Carbone, L.; Cattuto, C.; Gammaitoni, L.; Punturo, M.; Travasso, F.; Vocca, H. 2001: Thermal noise limit in the Virgo mirror suspension. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 461(1-3): 297-299
Garrett, S.L.; Hofler, T.; Gardner, D.L. 1987: Thermal noise limitations in u fiber optic seismic sensor. Journal of the Acoustical Society of America 82(1): S56-S57
Waite, R.I.; Pohm, A.V.; Comstock, C.S. 1988: Thermal noise limitations to 2×20‐μm2magnetoresistive memory element thresholds. Journal of Applied Physics 63(8): 3151-3152
Golder, J.; Nicolet, M.; Shumka, A. 1973: Thermal noise measurements on space-charge-limited hole current in silicon. Solid-State Electronics 16(5): 581-585
Triantis, D.; Birbas, A.; Kondis, D. 1996: Thermal noise modeling for short-channel MOSFETs. IEEE Transactions on Electron Devices 43(11): 1950-1955
Heidmann, A.; Cohadon, P.; Pinard, M. 1999: Thermal noise of a plano-convex mirror. Physics Letters A 263(1-2): 27-32
Bilger, H. 1973: Thermal noise of a silicon double-injection plasma diode. Solid-State Electronics 16(12): 1363-1365
Amico, P.; Bosi, L.; Gammaitoni, L.; Losurdo, G.; Marchesoni, F.; Mazzoni, M.; Punturo, M.; Stanga, R.; Toncelli, A.; Tonelli, M.; Travasso, F.; Vetrano, F.; Vocca, H. 2004: Thermal noise reduction for present and future gravitational wave detectors. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 518(1-2): 240-243
Vitale, S.; Barbara, B.; Cavalleri, A.; Cerdonio, M.; Ratnam, A. 1994: Thermal noise with 1/f spectral density in the random anisotropy system Dy Ni. Physica B: Condensed Matter 194-196: 259-260
Raver, N. 1982: Thermal noise, intermittent failures, and yield in Josephson circuits. IEEE Journal of Solid-State Circuits 17(5): 932-937
Gorodetsky, M.L. 2008: Thermal noises and noise compensation in high-reflection multilayer coating. Physics Letters A 372(46): 6813-6822
Müller, D.; De Groof, A.; Hansteen, V.; Peter, H. 2004: Thermal non-equilibrium in coronal loops: a road to complex evolution. Proceedings of the International Astronomical Union 2004(IAUS 223): 289-290
Bertolotti, M.; Fazio, E.; Ferrari, A.; Liakhou, G.; Gnappi, G.; Montenero, A.; Rossi, M.; Sibilia, C.; Zimin, L. 1990: Thermal non-linearities of semiconductor-doped glasses in the near-IR region. Materials Science and Engineering: B5(2): 143-145
Zube, D.M.; Myers, R.M. 1993: Thermal nonequilibrium in a low-power arcjet nozzle. Journal of Propulsion and Power 9(4): 545-552
Choquet, I. 1994: Thermal nonequilibrium modeling using the direct simulation Monte Carlo method: Application to rotational energy. Physics of Fluids 6(12): 4042-4053
Nagayama, K.; Mori, Y. 1998: Thermal nonequilibrium of the shock-compressed state of polymers realized by 1 GPa shock waves. Journal of Applied Physics 84(12): 6592-6599
Hood, A.W.; Priest, E.R. 1981: Thermal nonequilibrium: a trigger for solar flares?. Solar Physics 73(2): 289-311
Xiaogang, T.; Jun, L.; Chenyang, X. 2017: Thermal nonlinear effect in high Q factor silicon-on-insulator microring resonator. Optics Communications 395: 207-211
Rasouli, S.; Sakha, F.; Mojarrad, A.G.; Zakavi, S. 2017: Thermal nonlinear optical response of meso-tetraphenylporphyrin under aggregation conditions versus that in the absence of aggregation. Journal of Modern Optics 65(8): 1009-1017
Cason, M.; Bersani, D.; Antonioli, G.; Paolo Lottici, P.; Montenero, A.; Cavalli, M. 1999: Thermal nonlinear refraction in the dye-doped sol–gel x Ti O2·(100−x)Si O2 system. Optical Materials 12(4): 447-452
Karimzadeh, R.; Aleali, H.; Mansour, N. 2011: Thermal nonlinear refraction properties of Ag2S semiconductor nanocrystals with its application as a low power optical limiter. Optics Communications 284(9): 2370-2375
Elias, R.S.; Hassan, Q.M.; Sultan, H.; Al-Asadi, A.S.; Saeed, B.A.; Emshary, C. 2018: Thermal nonlinearities for three curcuminoids measured by diffraction ring patterns and Z-scan under visible CW laser illumination. Optics-Laser Technology 107: 131-141
Zeng, X.C.; Oxtoby, D.W.; Cheng, E. 1996: Thermal nucleation and cavitation in helium‐3 fluids. The Journal of Chemical Physics 104(10): 3726-3731
Dubos, H.; Girard, T.A.; Waysand, G.; Perrier, P.; Jeudy, V.; Limagne, D.; Seco, J.; Collar, J.I. 1998: Thermal nucleation of the normal state in superheated superconducting tin grains. Physical Review B 58(10): 6468-6475
Shulman, G.P. 1965: Thermal of degradation of polymers. I. Mass spectrometric thermal analysis. Journal of Polymer Science Part B: Polymer Letters 3(11): 911-915
Joaci, d.S.C.; Helder, N.d.A.; Ronaldo, d.N.; Hallyson, O.; José, A.F.C.; Armindo, B.L. 2016: Thermal of the Campina Grande - PB, Brazil and its environmental impacts. African Journal of Agricultural Research 11(38): 3651-3658
Guo, J.; Chen, X.; Li, Z. 2017: Thermal oil aging behavior of hydrogenated nitrile butadiene rubber/multi-walled carbon nanotube composites under free or compression state. Journal of Elastomers-Plastics 50(5): 448-462
Kämpfer, B.; Pavlenko, O P.; Peshier, A.; Hentschel, M.; Soff, G. 1997: Thermal open charm signals versus hard initial yields in ultrarelativistic heavy-ion collisions. Journal of Physics G: Nuclear and Particle Physics 23(12): 2001-2011
Stepien, L.; Roch, A.; Tkachov, R.; Leupolt, B.; Han, L.; van Ngo, N.; Leyens, C. 2017: Thermal operating window for PEDOT:PSS films and its related thermoelectric properties. Synthetic Metals 225: 49-54
Caselle, M.; Gliozzi, F.; Necco, S. 2001: Thermal operators and cluster topology in theq-state Potts model. Journal of Physics A: Mathematical and General 34(3): 351-355
Caselle, M.; Gliozzi, F. 2000: Thermal operators in Ising percolation. Journal of Physics A: Mathematical and General 33(12): 2333-2344
Haberfeld, J.L.; Reffner, J.A. 1976: Thermal optical analysis and differential scanning calorimetry of chemically crosslinked polyethylene. Thermochimica Acta 15(3): 307-313
Nonaka, K.; Kawaguchi, H.; Kawamura, Y.; Tsuda, H.; Kubodera, K. 1989: Thermal optical bistability in in Ga As/in Al as MQW etalons at 1.5 mu m wavelength. IEEE Photonics Technology Letters 1(3): 55-58
Xu, Y.; Li, Y. 2012: Thermal optical effect in axisymmetric structural laser resonator. Optics-Laser Technology 44(1): 114-117
Hsu, M.; Chang, H.; Chang, S. 2013: Thermal optical path difference analysis of off-axis lens ray trace foot-print. Optical Review 20(2): 153-154
Gülşen, G.; Naci Inci, M. 2002: Thermal optical properties of Ti O2 films. Optical Materials 18(4): 373-381
Gao, S.; Wang, W. 2021: Thermal optical properties, Q-switching and frequency tuning of an Nd : LGGG laser based on the 4F3/2 → 4I13/2 transition of a neodymium ion. Quantum Electronics 51(2): 149-152
Lewis, R.; Manzari, M.; Gethin, D. 2001: Thermal optimisation in the sand casting process. Engineering Computations 18(3-4): 392-417
Dong, D.; Humphries, T.D.; Sheppard, D.A.; Stansby, B.; Paskevicius, M.; Sofianos, M.; Chaudhary, A.; Dornheim, M.; Buckley, C.E. 2017: Thermal optimisation of metal hydride reactors for thermal energy storage applications. Sustainable Energy-Fuels 1(8): 1820-1829
He, Q.; Li, A.; Shen, Y.; Li, L. 2018: Thermal optimization and experimental research of high-speed universal pulverizer. Advances in Manufacturing 6(1): 83-94
Bishara, N.; Schulz, T.; Gecks, J.; Plagge, R.; Wehsener, J. 2017: Thermal optimization and performance analysis of an innovative wooden radiant heating system made for room temperature control- Laboratory and numerical investigation of prototypes. Energy and Buildings 138: 569-578
Lokhande, B.; Ambare, R.; Bharadwaj, S. 2014: Thermal optimization and supercapacitive application of electrodeposited Fe2O3 thin films. Measurement 47: 427-432
Kok, S.; Stander, N.; Roux, W. 1998: Thermal optimization in transient thermoelasticity using response surface approximations. International Journal for Numerical Methods in Engineering 43(1): 1-21
Liu, R.; Schreurs, D.; De Raedt, W.; Vanaverbeke, F.; Mertens, R.; De Wolf, I. 2011: Thermal optimization of Ga N-on-Si HEMTs with plastic package. Microelectronics Reliability 51(9-11): 1788-1791
He, P.; Jiao, Z.; Yan, L.; Wang, T. 2015: Thermal optimization of a tubular linear oscillating motor for directly driven LEHA application. Numerical Heat Transfer, Part A: Applications 69(4): 383-400
Liang, Y.; Su, H.; Lu, L.; Chen, W.; Sun, Y.; Zhang, P. 2014: Thermal optimization of an ultra-precision machine tool by the thermal displacement decomposition and counteraction method. International Journal of Advanced Manufacturing Technology 76(1-4): 635-645
Kim, D. 2014: Thermal optimization of branched-fin heat sinks subject to a parallel flow. International Journal of Heat and Mass Transfer 77: 278-287
Wu, W.; Wu, W.; Wang, S. 2017: Thermal optimization of composite PCM based large-format lithium-ion battery modules under extreme operating conditions. Energy Conversion and Management 153: 22-33
Weber, T. A.; Arent, J.; Steffens, L.; Balvers, J. M.; Duhovic, M. 2017: Thermal optimization of composite autoclave molds using the shift factor approach for boundary condition estimation. Journal of Composite Materials 51(12): 1753-1767
Jiang, G.; Huang, J.; Fu, Y.; Cao, M.; Liu, M. 2016: Thermal optimization of composite phase change material/expanded graphite for Li-ion battery thermal management. Applied Thermal Engineering 108: 1119-1125
Crema, L.; Sorgato, M.; Lucchetta, G. 2017: Thermal optimization of deterministic porous mold inserts for rapid heat cycle molding. International Journal of Heat and Mass Transfer 109: 462-469
Kim, D. 2016: Thermal optimization of internally finned tube with variable fin thickness. Applied Thermal Engineering 102: 1250-1261
Pesiri, D. R.; Jorgensen, B.; Dye, R. C. 2003: Thermal optimization of polybenzimidazole meniscus membranes for the separation of hydrogen, methane, and carbon dioxide. Journal of Membrane Science 218(1-2): 11-18
Joo, Y.; Kim, S.J. 2016: Thermal optimization of vertically oriented, internally finned tubes in natural convection. International Journal of Heat and Mass Transfer 93: 991-999
Shu, Q.; Demko, J.; Dorman, R.; Finan, D.; Hatfield, D.; Syromyatnikov, I.; Zolotov, A.; Mazur, P.; Peterson, T. 1993: Thermal optimum analyses and mechanical design of 10-k A, vapor-cooled power leads for SSC superconducting magnet tests at MTL. IEEE Transactions on Applied Superconductivity 3(1): 408-412
Férec, J.; Bertevas, E.; Khoo, B.; Ausias, G.; Phan-Thien, N. 2018: Thermal or electrical bulk properties of rod-filled composites. International Journal of Engineering Science 133: 219-230
Pamplin, B.; Milsom, J. 1981: Thermal oscillations in liquids of low prandtl number. Journal of Crystal Growth 52: 459-464
Koenig, S.; Brown Iii, R. 1959: Thermal oscillations in n-germanium at low temperature. Journal of Physics and Chemistry of Solids 10(2-3): 201-203
Biswas, S.; Mukherjee, K.; Mukherjee, D.C.; Moulik, S.P. 2002: Thermal oscillations in the bromate – oxalic acid – Mn SO4 – H2SO4 – acetone system: a calorimetric study. Canadian Journal of Chemistry 80(9): 1204-1209
Vink, H.; Chishti, S. 1976: Thermal osmosis in liquids. Journal of Membrane Science 1: 149-164
Sharma, P.K.; Hickey, G.S. 1994: Thermal outgassing behavior and photoemission studies of Haynes Alloy 214. Journal of Vacuum Science-Technology A: Vacuum, Surfaces, and Films 12(3): 867-872
Lenzen, M.; Turner, G.M.; Collins, R.E. 1999: Thermal outgassing of vacuum glazing. Journal of Vacuum Science-Technology A: Vacuum, Surfaces, and Films 17(3): 1002-1017
Reiter, F.; Camposilvan, J. 1982: Thermal outgassing properties of mechanically polished and of sand- and bead-blasted Inconel 600 surfaces up to 500°C. Vacuum 32(5): 227-232
Ogorelec, Z. 1999: Thermal output of a current-carrying ferromagnetic wire: hysteresis loss versus Joule heat. European Journal of Physics 20(3): 201-204
Wu, J.; Dong, J.; Wang, Y.; Gond, B.K. 2017: Thermal oxidation ageing effects on silicone rubber sealing performance. Polymer Degradation and Stability 135: 43-53
Hu, Y.; Zhang, Y.; Nutt, S. 2016: Thermal oxidation aging of polydicyclopentadiene and composites. Polymer Composites 39(5): 1742-1751
Kioseoglou, J.; Komninou, P.; Zervos, M. 2014: Thermal oxidation and facet-formation mechanisms of Si nanowires. Physica status solidi (RRL) - Rapid Research Letters 8(4): 307-311
Liu, J.; Yuan, J.; Li, H.; Pang, A.; Xu, P.; Tang, G.; Xu, X. 2021: Thermal oxidation and heterogeneous combustion of Al H3 and Al: a comparative study. Acta Astronautica 179: 636-645
Schwartz, G.; Griffiths, J.; Gualtieri, G. 1982: Thermal oxidation and native oxide-substrate reactions on in as and Inx Ga1−x as. Thin Solid Films 94(3): 213-222
Brady, D.; Fuss, F.; Gerstenberg, D. 1980: Thermal oxidation and resistivity of tantalum nitride films. Thin Solid Films 66(3): 287-302
Sun, Q.; Hu, T.; Fan, H.; Zhang, Y.; Hu, L. 2016: Thermal oxidation behavior and tribological properties of textured TC4 surface: Influence of thermal oxidation temperature and time. Tribology International 94: 479-489
Ahmad, M. 1987: Thermal oxidation behavior of an Al-Li-Cu-Mg-Zr alloy. Metallurgical and Materials Transactions A 18(4): 681-689
Abdi, S.; Bönisch, M.; Oswald, S.; Khoshkhoo, M.S.; Gruner, W.; Lorenzetti, M.; Wolff, U.; Calin, M.; Eckert, J.; Gebert, A. 2016: Thermal oxidation behavior of glass-forming Ti–Zr–(Nb)–Si alloys. Journal of Materials Research 31(9): 1264-1274
Xiao, H.; Ma, H.; Xue, C.; Zhuang, H.; Ma, J.; Zong, F.; Hu, W. 2005: Thermal oxidation behaviors of Ga N powders. Materials Letters 59(29-30): 4041-4043
Nie, X.; Yang, X.; Ma, Y.; Chen, L.; Yeap, K.; Zeng, K.; Li, D.; Pan, J.; Wang, X.; Cao, Q.; Ding, S.; Jiang, J. 2012: Thermal oxidation effect on corrosion behavior of Zr46Cu37.6Ag8.4Al8 bulk metallic glass. Intermetallics 22: 84-91
Huang, S.; Gao, Y.; Zhang, Y.; Chen, S.; Xiao, Q. 2019: Thermal oxidation etching strategy towards mesoporous hollow carbon spheres. Materials Letters 240: 253-257
Zhang, Y. 2015: Thermal oxidation fabrication of Ni O film for optoelectronic devices. Applied Surface Science 344: 33-37
Jiang, M.; Yu, H.; Li, X.; Lu, S.; Hu, X. 2017: Thermal oxidation induced high electrochemical activity of boron-doped nanocrystalline diamond electrodes. Electrochimica Acta 258: 61-70
De Meo, R.C.; Chow, T.P. 1995: Thermal oxidation kinetics of (100) and (111) silicon in nitrous oxide. Applied Physics Letters 67(4): 500-502
Tarani, E.; Chaliampalias, D.; Pavlidou, E.; Chrissafis, K.; Vourlias, G. 2016: Thermal oxidation kinetics of Cr Si2 powder synthesized by pack cementation process. Journal of Thermal Analysis and Calorimetry 125(1): 111-120
Ogawa, S.; Kawamura, T.; Takakuwa, Y. 2006: Thermal oxidation kinetics of an Si1−x Cx alloy layer (x≃0.1) on Si(001) surfaces monitored in real time by RHEED combined with AES. Materials Science and Engineering: B135(3): 210-214
Jin, Y.; Song, J.Y.; Jeong, S.; Kim, J.W.; Lee, T.G.; Kim, J.H.; Hahn, J. 2010: Thermal oxidation mechanism and stress evolution in Ta thin films. Journal of Materials Research 25(6): 1080-1086
Takakuwa, Y.; Nihei, M.; Horie, T.; Miyamoto, N. 1994: Thermal oxidation mechanism based on formation and diffusion of volatile Si O molecules. Journal of Non-Crystalline Solids 179: 345-353
Kosugi, R.; Fukuda, K.; Arai, K. 2003: Thermal oxidation of (0001) 4H-Si C at high temperatures in ozone-admixed oxygen gas ambient. Applied Physics Letters 83(5): 884-886
Trimaille, I.; Ganem, J.; Vickridge, I.C.; Rigo, S.; Battistig, G.; Szilagyi, E.; Baumvol, I.J.; Radtke, C.; Stedile, F.C. 2004: Thermal oxidation of 6H-Si C studied by oxygen isotopic tracing and narrow nuclear resonance profiling. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 219-220: 914-918
Kumar, S.; Narayanan, T.S.; Raman, S.G.S.; Seshadri, S. 2009: Thermal oxidation of CP-Ti: Evaluation of characteristics and corrosion resistance as a function of treatment time. Materials Science and Engineering: C29(6): 1942-1949
Suita, M.; Taguchi, T. 1989: Thermal oxidation of Cd Te surfaces and the properties of MOS diodes. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 283(2): 268-273
Felsche, J.; Kaldis, E. 1972: Thermal oxidation of Eu2Si O4- a topotactic solid state reaction. Journal of Solid State Chemistry 5(1): 49-56
Kato, Y.; Geib, K.M.; Gann, R.G.; Brusenback, P.R.; Wilmsen, C. 1984: Thermal oxidation of Ga P. Journal of Vacuum Science-Technology A: Vacuum, Surfaces, and Films 2(2): 588-592
Murarka, S.P. 1975: Thermal oxidation of Ga as. Applied Physics Letters 26(4): 180-181
Dedyulin, S.; Goncharova, L. 2012: Thermal oxidation of Ge-implanted Si: Role of defects. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 272: 334-337
Huang, J.; David, A.; Le Gac, P.; Lorthioir, C.; Coelho, C.; Richaud, E. 2019: Thermal oxidation of Poly(dicyclopentadiene)– kinetic modeling of double bond consumption. Polymer Degradation and Stability 166: 258-271
Soriano, L.; Abbate, M.; Fuggle, J.C.; Prieto, P.; Jiménez, C.; Sanz, J.M.; Galán, L.; Hofmann, S. 1993: Thermal oxidation of Ti N studied by means of soft x‐ray absorption spectroscopy. Journal of Vacuum Science-Technology A: Vacuum, Surfaces, and Films 11(1): 47-51
Zhang, Y.; Ma, G.; Zhang, X.; Li, S.; Tu, S. 2017: Thermal oxidation of Ti-6Al–4V alloy and pure titanium under external bending strain: Experiment and modelling. Corrosion Science 122: 61-73
Vaz, F.; Rebouta, L.; Andritschky, M.; da Silva, M.; Soares, J. 1997: Thermal oxidation of Ti1 − x Alx N coatings in air. Journal of the European Ceramic Society 17(15-16): 1971-1977
Luo, Y.; Chen, W.; Tian, M.; Teng, S. 2015: Thermal oxidation of Ti6Al4V alloy and its biotribological properties under serum lubrication. Tribology International 89: 67-71
Kumar, S.; Sankara Narayanan, T.; Ganesh Sundara Raman, S.; Seshadri, S. 2010: Thermal oxidation of Ti6Al4V alloy: Microstructural and electrochemical characterization. Materials Chemistry and Physics 119(1-2): 337-346
Luo, Y.; Yang, T.; Rao, X.; Zhu, J.; Li, M. 2017: Thermal oxidation of Zr-2.5Nb alloy and its biotribological properties. International Journal of Advanced Manufacturing Technology 96(5-8): 1539-1543
Oleksak, R.; Hostetler, E.; Flynn, B.; McGlone, J.; Landau, N.; Wager, J.; Stickle, W.; Herman, G. 2015: Thermal oxidation of Zr–Cu–Al–Ni amorphous metal thin films. Thin Solid Films 595: 209-213
Weller, K.; Jeurgens, L.P.; Wang, Z.; Mittemeijer, E.J. 2015: Thermal oxidation of amorphous Al0.44Zr0.56 alloys. Acta Materialia 87: 187-200
Siciliano, T.; Tepore, M.; Genga, A.; Micocci, G.; Siciliano, M.; Tepore, A. 2013: Thermal oxidation of amorphous Ga Se thin films. Vacuum 92: 65-69
Delozanne, J.; Desgardin, N.; Cuvillier, N.; Richaud, E. 2019: Thermal oxidation of aromatic epoxy-diamine networks. Polymer Degradation and Stability 166: 174-187
Balitskii, O.; Lutsiv, R.; Savchyn, V.; Stakhira, J. 1998: Thermal oxidation of cleft surface of in Se single crystal. Materials Science and Engineering: B56(1): 5-10
Beachell, H.C.; Beck, D.L. 1965: Thermal oxidation of deuterated polypropylenes. Journal of Polymer Science Part A: General Papers 3(2): 457-468
Shibryaeva, L.S.; Reshmin, Y.A.; Kuksenko, E.S.; Shatalova, O.V.; Krivandin, A.V.; Gorbunova, I.Y.; Kerber, M.L. 2007: Thermal oxidation of ester-modified isotactic polypropylene. Polymer Science Series A 49(1): 12-27
Salonen, J.; Lehto, V.; Laine, E. 1997: Thermal oxidation of free-standing porous silicon films. Applied Physics Letters 70(5): 637-639
Tang, C.; Bando, Y.; Liu, Z. 2003: Thermal oxidation of gallium nitride nanowires. Applied Physics Letters 83(15): 3177-3179
Nair, S.S.; Saha, T.; Dey, P.; Bhadra, S. 2020: Thermal oxidation of graphite as the first step for graphene preparation: effect of heating temperature and time. Journal of Materials Science 56(5): 3675-3691
Murarka, S.P.; Chang, C.C. 1980: Thermal oxidation of hafnium silicide films on silicon. Applied Physics Letters 37(7): 639-641
Schwartz, G.P.; Thiel, F.A.; Gualtieri, G.J. 1984: Thermal oxidation of in Asx P1−x. Journal of Vacuum Science-Technology A: Vacuum, Surfaces, and Films 2(3): 1252-1256
Wager, J.F.; Wilmsen, C.W. 1980: Thermal oxidation of in P. Journal of Applied Physics 51(1): 812-814
Yamaguchi, M.; Ando, K. 1980: Thermal oxidation of in P and properties of oxide film. Journal of Applied Physics 51(9): 5007-5012
Yamaguchi, M. 1981: Thermal oxidation of in P in phosphorus pentoxide vapor. Journal of Applied Physics 52(7): 4885-4887
Laughlin, D.; Wilmsen, C. 1980: Thermal oxidation of in as. Thin Solid Films 70(2): 325-332
Yamaguchi, M.; Yamamoto, A.; Sugiura, H.; Uemura, C. 1982: Thermal oxidation of in as and characterization of the oxide film. Thin Solid Films 92(4): 361-370
Ratcliffe, P.J.; Collins, R.A. 1988: Thermal oxidation of ion implanted copper. Physica Status Solidi (a) 108(2): 537-543
Zaharescu, T.; Setnescu, R.; Borbath, I. 2014: Thermal oxidation of irradiated magnetic fluids and their component surfactants and dispersing oils. Open Chemistry 12(7): 782-787
Whitlock, C.B.; Nawar, W.W. 1976: Thermal oxidation of mono-unsaturated short chain fatty acids: I. ethyl 3-hexenoate. Journal of the American Oil Chemists' Society 53(9): 586-591
Whitlock, C.B.; Nawar, W.W. 1976: Thermal oxidation of mono-unsaturated short chain fatty acids: II. Methyl hexenoate, hexenoic acid, and octenoic acid. Journal of the American Oil Chemists' Society 53(9): 592-594
Zetterling, C -.; Östling, M. 1994: Thermal oxidation of n- and p-type 6H-silicon carbide. Physica Scripta T 54: 291-293
Kambilafka, V.; Voulgaropoulou, P.; Dounis, S.; Iliopoulos, E.; Androulidaki, M.; Šály, V.; Ružinský, M.; Aperathitis, E. 2007: Thermal oxidation of n-type Zn N films made by -sputtering from a zinc nitride target, and their conversion into p-type films. Superlattices and Microstructures 42(1-6): 55-61
Bartur, M.; Nicolet, M. 1982: Thermal oxidation of nickel disilicide. Applied Physics Letters 40(2): 175-177
Nath, N.; Eyre, N.; Dearnaley, G. 1985: Thermal oxidation of nickel following cerium and platinum implantations. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 10-11: 580-582
Chow, T.P.; Hamzeh, K.; Steckl, A.J. 1983: Thermal oxidation of niobium silicide thin films. Journal of Applied Physics 54(5): 2716-2719
Matisová-Rychlá, L.; Rychlý, J. 2003: Thermal oxidation of nonstabilized and stabilized polymers and chemiluminescence. Journal of Polymer Science Part A: Polymer Chemistry 42(3): 648-660
Takakuwa, Y.; Nihei, M.; Miyamoto, N. 1997: Thermal oxidation of outdiffusing Si O with permeating O2 in a Si O2 film studied by angle-resolved X-ray photoelectron spectroscopy. Applied Surface Science 117-118: 141-146
Le Gendre, L.; Le Paven, C.; Haydoura, M.; Benzerga, R.; Marlec, F.; Sharaiha, A.; Cheviré, F.; Tessier, F.; Moréac, A. 2020: Thermal oxidation of oxynitride films as a strategy to achieve (Sr2Ta2O7)100-x(La2Ti2O7)x based oxide perovskite films with x = 1.65. Journal of the European Ceramic Society 40(16): 6293-6300
Gabbay, S.; Stivala, S. 1976: Thermal oxidation of poly(1-pentene): 1. Indentification of products and mechanisms. Polymer 17(1): 61-64
Standage, A.; Matkowsky, R. 1971: Thermal oxidation of polyacrylonitrile. European Polymer Journal 7(7): 775-783
Ng, C.Y.; Abdul Razak, K.; Lockman, Z. 2015: Thermal oxidation of seeds for the hydrothermal growth of WO3 nanorods on ITO glass substrate. Thin Solid Films 595: 73-78
Revesz, A.; Evans, R. 1967: Thermal oxidation of silicon as an impurity-controlled process. IEEE Transactions on Electron Devices 14(11): 789-790
Peev, G.; Racheva, T.; Dacheva, E.; Nedev, N. 1989: Thermal oxidation of silicon in O2-Si F4 mixtures. Thin Solid Films 169(1): 173-178
Massoud, H. 1997: Thermal oxidation of silicon in the ultrathin regime. Solid-State Electronics 41(7): 929-934
Scheer, K.C.; Rao, R.A.; Muralidhar, R.; Bagchi, S.; Conner, J.; Lozano, L.; Perez, C.; Sadd, M.; White Jr., B.E. 2003: Thermal oxidation of silicon nanocrystals in O2 and NO ambient. Journal of Applied Physics 93(9): 5637-5642
Grant, W.A.; Christodoulides, C.E.; Pogarides, D.C.; Williams, J.S. 1979: Thermal oxidation of silicon studied by high resolution Rutherford backscattering. Journal of Radioanalytical Chemistry 48(1-2): 277-286
Ritchie, K. 1976: Thermal oxidation of silicon wafer with ''striations'' from heavy phosphorus doping. Applied Physics Letters 28(7): 401-402
Prins, F E.; Single, C.; Zhou, F.; Heidemeyer, H.; Kern, D P.; Plies, E. 1999: Thermal oxidation of silicon-on-insulator dots. Nanotechnology 10(2): 132-134
Irene, E.A.; Ghez, R. 1987: Thermal oxidation of silicon: new experimental results and models. Applied Surface Science 30(1-4): 1-16
Chaudhuri, J.; Lee, R.; Nyakiti, L.; Gu, Z.; Edgar, J.; Li, P. 2008: Thermal oxidation of single crystal aluminum nitride - a high resolution transmission electron microscopy study. Materials Letters 62(16): 2465-2468
Varma, H.V.; Varma, J. 1987: Thermal oxidation of staurolite using Mössbauer effect. Hyperfine Interactions 35(1-4): 867-870
Olsen, S.; O'Neill, A.; Norris, D.; Cullis, A.; Bull, S.; Chattopadhyay, S.; Kwa, K.; Driscoll, L.; Waite, A.; Tang, Y.; Evans, A. 2004: Thermal oxidation of strained Si/Si Ge: impact of surface morphology and effect on MOS devices. Materials Science and Engineering: B109(1-3): 78-84
Endres, J.G.; Bhalerao, V.R.; Kummerow, F.A. 1962: Thermal oxidation of synthetic triglycerides I. composition of oxidized triglycerides. Journal of the American Oil Chemists Society 39(2): 118-121
Endres, J.G.; Bhalerao, V.R.; Kummerow, F.A. 1962: Thermal oxidation of synthetic triglycerides. II. Analysis of the volatile condensable and noncondensable phases. Journal of the American Oil Chemists' Society 39(3): 159-162
Saraswat, K.C.; Nowicki, R.S.; Moulder, J.F. 1982: Thermal oxidation of tantalum silicide in O2and H2O. Applied Physics Letters 41(12): 1127-1129
Oster, M.; Tapp, J.; Hagenow, A.; Möller, A. 2017: Thermal oxidation of the intermetallic phases Al 8 Mo 3 and Al Mo 3. Journal of Solid State Chemistry 251: 233-236
Jamesh, M.; Sankara Narayanan, T.; Chu, P.K. 2013: Thermal oxidation of titanium: Evaluation of corrosion resistance as a function of cooling rate. Materials Chemistry and Physics 138(2-3): 565-572
Jiang, H.; Petersson, C.; Nicolet, M. 1986: Thermal oxidation of transition metal silicides. Thin Solid Films 140(1): 115-130
Bartur, M. 1983: Thermal oxidation of transition metal silicides: the role of mass transport. Thin Solid Films 107(1): 55-65
López, M.F.; Gutiérrez, A.; Jiménez, J.A.; Martinesi, M.; Stio, M.; Treves, C. 2010: Thermal oxidation of vanadium-free Ti alloys: An X-ray photoelectron spectroscopy study. Materials Science and Engineering: C30(3): 465-471
Arrieta, J.S.; Richaud, E.; Fayolle, B.; Nizeyimana, F. 2016: Thermal oxidation of vinyl ester and unsaturated polyester resins. Polymer Degradation and Stability 129: 142-155
Sato, S.; Inoue, T.; Sasaki, H. 1981: Thermal oxidation of β-Ta below 500 °C. Thin Solid Films 86(1): 21-30
Rychlý, J.; Matisová-Rychlá, L.; Lazár, M.; Janigová, I.; Strlič, M.; Kočar, D.; Hanus, J.; Mináriková, J.; Katuščák, S. 2006: Thermal oxidation of cellulose investigated by chemiluminescence. the effect of magnesium and calcium carbonates and of different p Hs. Comptes Rendus Chimie 9(11-12): 1425-1432
Liu, P.; Liu, X.; Kubota, S.; Huang, P.; Wada, Y. 2019: Thermal oxidation process and characteristic of abietic acid and gum rosin by accelerating rate calorimeter (ARC). Journal of Thermal Analysis and Calorimetry 138(1): 479-488
Ren, F.; Zheng, Y.; Liu, X.; Yang, Q.; Zhang, Q.; Shen, F. 2015: Thermal oxidation reaction process and oxidation kinetics of abietic acid. RSC Advances 5(22): 17123-17130
Shinde, S.L.; Nanda, K.K. 2013: Thermal oxidation strategy for the synthesis of phase-controlled Ge O2and photoluminescence characterization. CrystEngComm 15(6): 1043-1046
Zhao, X.; Cao, M.; Hu, C. 2013: Thermal oxidation synthesis hollow Mo O3 microspheres and their applications in lithium storage and gas-sensing. Materials Research Bulletin 48(6): 2289-2295
Kurimoto, H.; Shibata, K.; Kimura, C.; Aoki, H.; Sugino, T. 2006: Thermal oxidation temperature dependence of 4H-Si C MOS interface. Applied Surface Science 253(5): 2416-2420
Tong, G.; Li, Y.; Wang, F.; Huang, Y.; Fang, B.; Wang, X.; Zhu, H.; Li, L.; Shen, Y.; Zheng, Q.; Liang, Q.; Yan, M.; Qin, Y.; Ding, J. 2013: Thermal oxidation-grown vanadium dioxide thin films on FTO (Fluorine-doped tin oxide) substrates. Infrared Physics-Technology 61: 37-41
Zhou, B.; Hu, H.; Jiao, Z.; Tang, Y.; Wan, P.; Yuan, Q.; Hu, Q.; Yang, X.J. 2021: Thermal oxidation–electroreduction modified 3D Ni Cu for efficient alkaline hydrogen evolution reaction. International Journal of Hydrogen Energy 46(43): 22292-22302
Balch, A.L.; Sohn, Y.S. 1971: Thermal oxidative addition of o-quinones to low-valent metal complexes. Journal of the American Chemical Society 93(5): 1290-1291
Shi, K.; Ye, L.; Li, G. 2016: Thermal oxidative aging behavior and stabilizing mechanism of highly oriented polyamide 6. Journal of Thermal Analysis and Calorimetry 126(2): 795-805
Gao, Y.; Gu, F.; Zhao, Y. 2013: Thermal oxidative aging characterization of SBS modified asphalt. Journal of Wuhan University of Technology-Mater. Sci. Ed. 28(1): 88-91
Xiang, L.; Cheng, J.; Kang, S. 2015: Thermal oxidative aging mechanism of crumb rubber/SBS composite modified asphalt. Construction and Building Materials 75: 169-175
Zhang, C.; Cao, B.; Li, P. 2018: Thermal oxidative crosslinking of phenolphthalein-based cardo polyimides with enhanced gas permeability and selectivity. Journal of Membrane Science 546: 90-99
Zhao, H.; Song, H.; Tao, X.; Chen, G.; Wang, A.; Chou, L. 2021: Thermal oxidative degradation and ageing performance of silicone rubber filled with attapulgite. Chinese Journal of Chemical Physics 34(3): 309-322
Du, X.; Zhao, C.; Wang, Y.; Zhou, Q.; Deng, Y.; Qu, M.; Yang, B. 2006: Thermal oxidative degradation behaviours of flame-retardant thermotropic liquid crystal copolyester/PET blends. Materials Chemistry and Physics 98(1): 172-177
Gupta, M.C.; Deshmukh, V.G. 1982: Thermal oxidative degradation of poly-lactic acid. Colloid and Polymer Science 260(3): 308-311
Gupta, M.C.; Deshmukh, V.G. 1982: Thermal oxidative degradation of poly-lactic acid. Colloid-Polymer Science 260(5): 514-517
de Carvalho, C.L.; Rosa, D.S. 2013: Thermal oxidative degradation of polypropylene-containing pro-oxidants. Journal of Thermal Analysis and Calorimetry 115(2): 1627-1632
Guo, L.; Huang, G.; Zheng, J.; Li, G. 2013: Thermal oxidative degradation of styrene-butadiene rubber (SBR) studied by 2D correlation analysis and kinetic analysis. Journal of Thermal Analysis and Calorimetry 115(1): 647-657
Yutanova, S.L.; Berezin, M.B.; Semeikin, A.S.; Antina, E.V.; Guseva, G.B.; V'yugin, A.I. 2013: Thermal oxidative degradation of the functionally substituted 2,2′-dipyrrolylmethenes hydrobromides and difluoroborates. Russian Journal of General Chemistry 83(3): 545-551
Guseva, G.B.; Antina, E.V.; Vyugin, A.I. 2008: Thermal oxidative destruction of isomeric dipyrrolylmethanes. Journal of Thermal Analysis and Calorimetry 92(3): 735-737
Ren, J.; Liu, X.; Zhang, L.; Liu, Q.; Gao, R.; Dai, W. 2017: Thermal oxidative etching method derived graphitic C3N4: highly efficient metal-free catalyst in the selective epoxidation of styrene. RSC Advances 7(9): 5340-5348
Paciorek, K.; Masuda, S.; Lin, W.; Nakahara, J. 1996: Thermal oxidative stability of perfluoropolyalkylethers and development of quantitative structure-stability relationships. Journal of Fluorine Chemistry 76(1): 21-27
Ryzhova, O.G.; Storozhenko, P.A.; Gerasimov, K.N.; Timofeev, P.A.; Kurishev, A.O.; Yakimova, A.Y.; Drachev, A.I.; Timofeev, I.A.; Kuznetsova, M.G. 2020: Thermal oxidative stability of yttrium containing oligomeric silazanes with organoelement substituents and multiceramics on their basis. Russian Chemical Bulletin 69(8): 1503-1510
Wang, P.; Liu, J.; Yue, Z.; Li, R. 1992: Thermal oxidative stabilization of polyacrylonitrile precursor fiber- progression of morphological structure and mechanical properties. Carbon 30(1): 113-120
Awaji, N.; Ohkubo, S.; Nakanishi, T.; Aoyama, T.; Sugita, Y.; Takasaki, K.; Komiya, S. 1997: Thermal oxide growth at chemical vapor deposited Si O2/Si interface during annealing evaluated by difference x-ray reflectivity. Applied Physics Letters 71(14): 1954-1956
Wu, M.; Wagner, S. 2001: Thermal oxide of polycrystalline silicon on steel foil as a thin-film transistor gate dielectric. Applied Physics Letters 78(23): 3729-3731
Masson, D.P.; Lockwood, D.J.; Graham, M.J. 1997: Thermal oxide on Cd Se. Journal of Applied Physics 82(4): 1632-1639
Jiao, H.; Yang, H. 2009: Thermal oxide synthesis and characterization of Fe3O4 nanorods and Fe2O3 nanowires. Science in China Series B: Chemistry 52(5): 599-604
Duch, J.; Stelmachowski, P.; Monteverde Videla, A.H.; Gajewska, M.; Kotarba, A.; Specchia, S. 2019: Thermal oxygen activation followed by in situ work function measurements over carbon-supported noble metal-based catalysts. International Journal of Hydrogen Energy 44(31): 16648-16656
Rodenbough, P.P.; Chan, S. 2018: Thermal oxygen exchange cycles in mixed manganese perovskites. Ceramics International 44(2): 1343-1347
Dang, N.D. 2007: Thermal pairing in Richardson model. Nuclear Physics A 784(1-4): 147-160
Singh, A.; Tadmor, E.B. 2015: Thermal parameter identification for non-Fourier heat transfer from molecular dynamics. Journal of Computational Physics 299: 667-686
Robinson, R.D.; Miaoulis, I.N. 1994: Thermal parameters affecting low temperature zone‐melting recrystallization of films. Journal of Applied Physics 75(3): 1771-1782
Tomaszewska, A.; Moskal, G.; Migas, D.; Mikuśkiewicz, M.; Maciąg, T. 2018: Thermal parameters determination of Co–Al–W as-cast alloy homogenization by DTA analysis. Journal of Thermal Analysis and Calorimetry 134(1): 157-164
Garmendia, I.; Anglada, E. 2022: Thermal parameters identification in the correlation of spacecraft thermal models against thermal test results. Acta Astronautica 191: 270-278
Mahadevan, C. 2008: Thermal parameters of Mg SO4·7H2O and Ni SO4·7H2O crystals added with urea and thiourea. Physica B: Condensed Matter 403(18): 3164-3167
Pelá, C.A.; Rocha, S.; de Paula, E.; Baffa, O. 1998: Thermal parameters of dental materials determined by photoacoustic phase lag measurements. Review of Scientific Instruments 69(9): 3392-3397
Klos, J.; Nowicki, P.; Cizmarik, J. 2007: Thermal parameters of phenylcarbamic acid derivatives using calculated molecular descriptors with MLR and ANN. Journal of Thermal Analysis and Calorimetry 91(1): 203-212
Labus, M.; Labus, K.; Bujok, P. 2019: Thermal parameters of roofing slates from Czech Republic. Journal of Thermal Analysis and Calorimetry 140(5): 2215-2223
Ivanov, V.A.; Lebedev, V.I. 1970: Thermal parameters of ruby laser operating in repetitive pulse mode. Journal of Applied Spectroscopy 13(1): 885-889
Anushya, G.; Freeda, T.H. 2021: Thermal parameters of undoped and medicines doped calcium hydrogen phosphate dihydrate and magnesium ammonium phosphate hexahydrate crystals. Journal of Thermal Analysis and Calorimetry 146(5): 1983-1989
Hsueh, K.; Chen, W.; Liu, S.; Shu, C. 2014: Thermal parameters study of 1,1-bis(tert-butylperoxy)cyclohexane at low heating rates with differential scanning calorimetry. Journal of Thermal Analysis and Calorimetry 118(3): 1675-1683
Grach, S.; Mityakov, N.; Rapoport, V.; Trakhtengertz, V. 1981: Thermal parametric turbulence in a plasma. Physica D: Nonlinear Phenomena 2(1): 102-106
Zablotskii, V. 2001: Thermal partial vortex depinning and channel formation in type-Ii superconductors. Superconductor Science and Technology 14(7): L25-L30
Huang, D.; Li, K.; Tian, G.Y.; Imam Sunny, A.; Chen, X.; Tang, C.; Wu, J.; Zhang, H.; Zhao, A. 2016: Thermal pattern reconstruction of surface condition on freeform-surface using eddy current pulsed thermography. Sensors and Actuators A: Physical 251: 248-257
Hung, M.; Ju, Y.S. 2008: Thermal patterning of amorphous fluoropolymer layers. Sensors and Actuators A: Physical 148(1): 111-114
Bartlett, A.A. 1982: Thermal patterns in the snow. The Physics Teacher 20(1): 36-37
Bartlett, A.A. 1976: Thermal patterns in the snow, Part i. The Physics Teacher 14(1): 14-18
Bartlett, A.A. 1999: Thermal patterns in the snow: Structure of a roof. The Physics Teacher 37(2): 120-121
Munari, F.; Trestianu, S. 1983: Thermal peak splitting in capillary gas chromatography. Journal of Chromatography A 279: 457-472
Lohrasbi, S.; Gorji-Bandpy, M.; Ganji, D.D. 2017: Thermal penetration depth enhancement in latent heat thermal energy storage system in the presence of heat pipe based on both charging and discharging processes. Energy Conversion and Management 148: 646-667
Xiong, J.; Zhou, X.; Lian, Z.; You, J.; Lin, Y. 2016: Thermal perception and skin temperature in different transient thermal environments in summer. Energy and Buildings 128: 155-163
Elnabawi, M.H.; Hamza, N.; Dudek, S. 2016: Thermal perception of outdoor urban spaces in the hot arid region of Cairo, Egypt. Sustainable Cities and Society 22: 136-145
Wang, F.; Tan, J.; Yong, S.; Tan, H.; Chu, S. 2014: Thermal performance analyses of porous media solar receiver with different irradiative transfer models. International Journal of Heat and Mass Transfer 78: 7-16
Du, H.; Li, J.; Zhu, W.; Yao, Z.; Cui, E.; Lv, M. 2018: Thermal performance analysis and comparison of stratospheric airships with rotatable and fixed photovoltaic array. Energy Conversion and Management 158: 373-386
Wang, X.; Barbanotti, S.; Eschke, J.; Jensch, K.; Klos, R.; Maschmann, W.; Petersen, B.; Sawlanski, O. 2014: Thermal performance analysis and measurements of the prototype cryomodules of European XFEL accelerator - part i. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 763: 701-710
Wang, X.; Barbanotti, S.; Eschke, J.; Jensch, K.; Klos, R.; Maschmann, W.; Petersen, B.; Sawlanski, O. 2014: Thermal performance analysis and measurements of the prototype cryomodules of European XFEL accelerator- Part Ii. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 763: 688-700
Han, R.; Zou, Z.; Ge, R.; Li, S.; Bian, L.; Sun, L.; Sang, M.; Ye, R.; Peng, Q.; Zhang, X.; Zhang, J.; Zhang, Z.; Zhang, J.; Xu, M.; Chang, Z.; Huang, T.; He, F.; Liu, C. 2019: Thermal performance analysis and operation of the spoke cavity cryomodules for C-ADS Injector-i. Cryogenics 101: 63-74
Han, C.; Sun, H.; Li, Z. 2018: Thermal performance analysis and optimization design for LNG submerged combustion vaporizer. Cryogenics 95: 47-56
Li, B.; Zhai, X.; Cheng, X. 2019: Thermal performance analysis and optimization of multiple stage latent heat storage unit based on entransy theory. International Journal of Heat and Mass Transfer 135: 149-157
Brottier, L.; Bennacer, R. 2020: Thermal performance analysis of 28 PVT solar domestic hot water installations in Western Europe. Renewable Energy 160: 196-210
Mahbubul, I.; Saadah, A.; Saidur, R.; Khairul, M.; Kamyar, A. 2015: Thermal performance analysis of Al2O3/R-134a nanorefrigerant. International Journal of Heat and Mass Transfer 85: 1034-1040
Kamrani, H.; Yu, F.; Frank, K.; Strempel, K.; Fatahilah, M.F.; Wasisto, H.S.; Römer, F.; Waag, A.; Witzigmann, B. 2018: Thermal performance analysis of Ga N nanowire and fin-shaped power transistors based on self-consistent electrothermal simulations. Microelectronics Reliability 91: 227-231
Han, Y.; Guo, H.; Zhang, X.; Yin, F.; Chu, K.; Fan, Y. 2011: Thermal performance analysis of LED with multichips. Journal of Wuhan University of Technology-Mater. Sci. Ed. 26(6): 1089-1092
Yadav, C.; Sahoo, R.R. 2020: Thermal performance analysis of MWCNT-based capric acid PCM thermal energy storage system. Journal of Thermal Analysis and Calorimetry 146(4): 1539-1550
Xie, J.; Wang, W.; Liu, J.; Pan, S. 2016: Thermal performance analysis of PCM components heat storage using mechanical ventilation: Experimental results. Energy and Buildings 123: 169-178
Chiu, H.; Jang, J.; Yan, W.; Shiao, R. 2017: Thermal performance analysis of a 30 k W switched reluctance motor. International Journal of Heat and Mass Transfer 114: 145-154
Cheng, X.; Zhai, X. 2018: Thermal performance analysis of a cascaded cold storage unit using multiple PCMs. Energy 143: 448-457
Tamuli, B.R.; Saikia, S.S.; Nath, S.; Bhanja, D. 2020: Thermal performance analysis of a co-axial evacuated tube collector with single and two-phase flow consideration under North-eastern India climatic condition. Solar Energy 196: 107-124
Arya, A.; Sarafraz, M.M.; Shahmiri, S.; Madani, S.A.H.; Nikkhah, V.; Nakhjavani, S.M. 2017: Thermal performance analysis of a flat heat pipe working with carbon nanotube-water nanofluid for cooling of a high heat flux heater. Heat and Mass Transfer 54(4): 985-997
Sakhaei, S.A.; Valipour, M.S. 2020: Thermal performance analysis of a flat plate solar collector by utilizing helically corrugated risers: An experimental study. Solar Energy 207: 235-246
Zhang, L.; Li, J.; Meng, J.; Du, H.; Lv, M.; Zhu, W. 2018: Thermal performance analysis of a high-altitude solar-powered hybrid airship. Renewable Energy 125: 890-906
Husain, A.; Ariz, M.; Al-Rawahi, N.Z.; Ansari, M. 2016: Thermal performance analysis of a hybrid micro-channel, -pillar and -jet impingement heat sink. Applied Thermal Engineering 102: 989-1000
Xia, Q.; Zhou, L.; Zhang, J. 2018: Thermal performance analysis of a long-span suspension bridge with long-term monitoring data. Journal of Civil Structural Health Monitoring 8(4): 543-553
Alqahtani, T.; Mellouli, S.; Bamasag, A.; Askri, F.; Phelan, P.E. 2020: Thermal performance analysis of a metal hydride reactor encircled by a phase change material sandwich bed. International Journal of Hydrogen Energy 45(43): 23076-23092
Katsura, T.; Memon, S.; Radwan, A.; Nakamura, M.; Nagano, K. 2020: Thermal performance analysis of a new structured-core translucent vacuum insulation panel in comparison to vacuum glazing: Experimental and theoretically validated analyses. Solar Energy 199: 326-346
Okonkwo, E.C.; Essien, E.A.; Akhayere, E.; Abid, M.; Kavaz, D.; Ratlamwala, T.A. 2018: Thermal performance analysis of a parabolic trough collector using water-based green-synthesized nanofluids. Solar Energy 170: 658-670
Qiu, Y.; Li, M.; He, Y.; Tao, W. 2017: Thermal performance analysis of a parabolic trough solar collector using supercritical CO2 as heat transfer fluid under non-uniform solar flux. Applied Thermal Engineering 115: 1255-1265
Tuncer, A.D.; Sözen, A.; Khanlari, A.; Amini, A.; Şirin, C. 2020: Thermal performance analysis of a quadruple-pass solar air collector assisted pilot-scale greenhouse dryer. Solar Energy 203: 304-316
Xamán, J.; Rodriguez-Ake, A.; Zavala-Guillén, I.; Hernández-Pérez, I.; Arce, J.; Sauceda, D. 2020: Thermal performance analysis of a roof with a PCM-layer under Mexican weather conditions. Renewable Energy 149: 773-785
Diao, Y.; Qi, N.; Wang, Z.; Zhao, Y.; Chen, C.; Wang, Z. 2021: Thermal performance analysis of a solar air collection–cascade storage system integrated with micro-heat pipe arrays. Solar Energy 224: 1271-1290
Chinnici, A.; Tian, Z.F.; Lim, J.H.; Nathan, G.J.; Dally, B.B. 2018: Thermal performance analysis of a syngas-fuelled hybrid solar receiver combustor operated in the MILD combustion regime. Combustion Science and Technology 191(1): 2-17
Cornaro, C.; Sapori, D.; Bucci, F.; Pierro, M.; Giammanco, C. 2015: Thermal performance analysis of an emergency shelter using dynamic building simulation. Energy and Buildings 88: 122-134
Bhuvad, S.S.; Azad, R.; Lanjewar, A. 2022: Thermal performance analysis of apex-up discrete arc ribs solar air heater-an experimental study. Renewable Energy 185: 403-415
Chen, Y.; Pei, X.; Han, B. 2021: Thermal performance analysis of building construction with insulated walls in summer days and nights. Journal of Central South University 28(11): 3613-3625
Elbahjaoui, R.; El Qarnia, H.; Naimi, A. 2018: Thermal performance analysis of combined solar collector with triple concentric-tube latent heat storage systems. Energy and Buildings 168: 438-456
Wang, Y.; Lei, R.; Wang, H.; Wang, S.; Bai, J. 2019: Thermal performance analysis of fin-and-tube heat exchanger circuit in supercritical hydrogen refrigeration cycle system. International Journal of Hydrogen Energy 44(56): 29765-29775
Rehman, T.; Ali, H.M. 2019: Thermal performance analysis of metallic foam-based heat sinks embedded with RT-54HC paraffin: an experimental investigation for electronic cooling. Journal of Thermal Analysis and Calorimetry 140(3): 979-990
Zhou, D.; Wu, S.; Wu, Z.; Yu, X. 2021: Thermal performance analysis of multi-slab phase change thermal energy storage unit with heat transfer enhancement approaches. Renewable Energy 172: 46-56
Gultekin, A.; Aydin, M.; Sisman, A. 2016: Thermal performance analysis of multiple borehole heat exchangers. Energy Conversion and Management 122: 544-551
Asmaie, L.; Haghshenasfard, M.; Mehrabani-Zeinabad, A.; Nasr Esfahany, M. 2013: Thermal performance analysis of nanofluids in a thermosyphon heat pipe using CFD modeling. Heat and Mass Transfer 49(5): 667-678
Mahapatra, A.; Tripathy, P.P. 2019: Thermal performance analysis of natural convection solar dryers under no load condition: experimental investigation and numerical simulation. International Journal of Green Energy 16(15): 1448-1464
Yang, A.; Chen, L.; Xie, Z.; Feng, H.; Sun, F. 2016: Thermal performance analysis of non-uniform height rectangular fin based on constructal theory and entransy theory. Science China Technological Sciences 59(12): 1882-1891
Wang, W.; He, X.; Hou, Y.; Qiu, J.; Han, D.; Shuai, Y. 2021: Thermal performance analysis of packed-bed thermal energy storage with radial gradient arrangement for phase change materials. Renewable Energy 173: 768-780
Hossain, M.; Pandey, A.; Selvaraj, J.; Abd Rahim, N.; Rivai, A.; Tyagi, V. 2019: Thermal performance analysis of parallel serpentine flow based photovoltaic/thermal (PV/T) system under composite climate of Malaysia. Applied Thermal Engineering 153: 861-871
Chang, S.J.; Wi, S.; Lee, J.; Kim, S. 2019: Thermal performance analysis of phase change materials composed of double layers considering heating and cooling period. Journal of Industrial and Engineering Chemistry 72: 255-264
Wang, F.; Shuai, Y.; Tan, H.; Yu, C. 2013: Thermal performance analysis of porous media receiver with concentrated solar irradiation. International Journal of Heat and Mass Transfer 62: 247-254
Hung, T.; Huang, Y.; Yan, W. 2013: Thermal performance analysis of porous-microchannel heat sinks with different configuration designs. International Journal of Heat and Mass Transfer 66: 235-243
Ghasemi, S.E.; Ranjbar, A.A. 2016: Thermal performance analysis of solar parabolic trough collector using nanofluid as working fluid: a CFD modelling study. Journal of Molecular Liquids 222: 159-166
Guene Lougou, B.; Shuai, Y.; Xing, H.; Yuan, Y.; Tan, H. 2017: Thermal performance analysis of solar thermochemical reactor for syngas production. International Journal of Heat and Mass Transfer 111: 410-418
Ahmed, N.; Elfeky, K.; Lu, L.; Wang, Q. 2020: Thermal performance analysis of thermocline combined sensible-latent heat storage system using cascaded-layered PCM designs for medium temperature applications. Renewable Energy 152: 684-697
Arabkoohsar, A.; Alsagri, A.S.; Khosravi, M. 2019: Thermal performance analysis of triple pipes for district heating systems. Journal of Thermal Analysis and Calorimetry 139(3): 1993-2003
Khairul, M.; Doroodchi, E.; Azizian, R.; Moghtaderi, B. 2017: Thermal performance analysis of tunable magnetite nanofluids for an energy system. Applied Thermal Engineering 126: 822-833
Lee, S.; Kim, G.; Lee, Y.; Kim, G. 2014: Thermal performance analysis of vacuum variable-temperature blackbody system. Infrared Physics-Technology 64: 97-102
Fung, S.F.; Lu, L. 2017: Thermal performance analysis on different types of glazing of public rental housing in Hong Kong. Procedia Engineering 205: 794-801
Shi, Y.; Zha, B.; Su, Q.; Wang, J.; Li, S. 2021: Thermal performance and ablation characteristics of C/C-Si C for thermal protection of hypersonic vehicle. Journal of the European Ceramic Society 41(11): 5427-5436
Duan, Q.; Zhao, Y.; Wang, J. 2020: Thermal performance and condensation risk of single-pane glazing with low emissivity coatings. MRS Advances 5(50): 2555-2564
Cunha, S.; Aguiar, J.B.; Tadeu, A. 2016: Thermal performance and cost analysis of mortars made with PCM and different binders. Construction and Building Materials 122: 637-648
Li, G.; Ni, Z.; Liu, Y.; Xia, M.; Luo, Y. 2018: Thermal performance and decomposition kinetics of RDX/AP/Si O2 intermolecular explosive. Journal of Thermal Analysis and Calorimetry 132(3): 1969-1978
Mohamad, K.; Ferrer, P. 2021: Thermal performance and design parameters investigation of a novel cavity receiver unit for parabolic trough concentrator. Renewable Energy 168: 692-704
Lamrani, B.; Draoui, A. 2020: Thermal performance and economic analysis of an indirect solar dryer of wood integrated with packed-bed thermal energy storage system: a case study of solar thermal applications. Drying Technology 39(10): 1371-1388
Akeiber, H.J.; Hosseini, S.E.; Hussen, H.M.; Wahid, M.A.; Mohammad, A.T. 2017: Thermal performance and economic evaluation of a newly developed phase change material for effective building encapsulation. Energy Conversion and Management 150: 48-61
Anis Akrouch, G.; Sánchez, M.; Briaud, J. 2020: Thermal performance and economic study of an energy piles system under cooling dominated conditions. Renewable Energy 147: 2736-2747
Huu-Quan, D.; Memarian, A.; Izadi, M.; Shehzad, S.A. 2020: Thermal performance and effectiveness of a dual-porous domestic heat exchanger for building heating application. Renewable Energy 162: 1874-1889
Kyriakidis, A.; Michael, A.; Illampas, R.; Charmpis, D.C.; Ioannou, I. 2018: Thermal performance and embodied energy of standard and retrofitted wall systems encountered in Southern Europe. Energy 161: 1016-1027
Prakash, O.; Ahmad, A.; Kumar, A.; Mozammil Hasnain, S.; Zare, A.; Verma, P. 2021: Thermal performance and energy consumption analysis of retail buildings through daylighting: a numerical model with experimental validation. Materials Science for Energy Technologies 4: 367-382
Sovetova, M.; Memon, S.A.; Kim, J. 2019: Thermal performance and energy efficiency of building integrated with PCMs in hot desert climate region. Solar Energy 189: 357-371
Mwesigye, A.; Huan, Z.; Meyer, J.P. 2016: Thermal performance and entropy generation analysis of a high concentration ratio parabolic trough solar collector with Cu-Therminol®VP-1 nanofluid. Energy Conversion and Management 120: 449-465
Shen, H.; Xie, G.; Wang, C. 2020: Thermal performance and entropy generation of novel X-structured double layered microchannel heat sinks. Journal of the Taiwan Institute of Chemical Engineers 111: 90-104
Duan, Z.; Xie, G.; Shen, H.; Wang, C. 2021: Thermal performance and entropy generation of single‐layer and double‐layer constructal Y‐shaped bionic microchannel heat sinks. International Journal of Energy Research 45(6): 9449-9462
Alshuhail, K.; Taleb, H. 2020: Thermal performance and experimental assessment of building orientations in the United Arab Emirates (UAE). Science and Technology for the Built Environment 26(10): 1461-1489
Irshidat, M.R.; Al-Saleh, M.H. 2018: Thermal performance and fire resistance of nanoclay modified cementitious materials. Construction and Building Materials 159: 213-219
Zhu, H.; Liu, M.; Yuen, R.K.; Leung, C.K.; Kim, J. 2012: Thermal performance and flame retardancy studies of vinyl ester and glass fiber reinforced plastic composites containing nanoclay. Journal of Composite Materials 48(2): 165-177
Gallegos Lazcano, M.A.; Yu, W. 2014: Thermal performance and flammability of phase change material for medium and elevated temperatures for textile application. Journal of Thermal Analysis and Calorimetry 117(1): 9-17
Kloczko, S.; Faghri, A. 2020: Thermal performance and flow characteristics of two-phase loop thermosyphons. Numerical Heat Transfer, Part A: Applications 77(7): 683-701
Azizi, Z.; Alamdari, A.; Malayeri, M. 2016: Thermal performance and friction factor of a cylindrical microchannel heat sink cooled by Cu-water nanofluid. Applied Thermal Engineering 99: 970-978
Singh, S.; Negi, J.S.; Bisht, S.; Sah, H. 2019: Thermal performance and frictional losses study of solid hollow circular disc with rectangular wings in circular tube. Heat and Mass Transfer 55(10): 2975-2986
Ghritlahre, H.K.; Sahu, P.K.; Chand, S. 2020: Thermal performance and heat transfer analysis of arc shaped roughened solar air heater – An experimental study. Solar Energy 199: 173-182
Ge, Z.; Yao, X.; Wang, X.; Zhang, W.; Yang, T. 2018: Thermal performance and microstructure of oil well cement paste containing subsphaeroidal konilite flour in HTHP conditions. Construction and Building Materials 172: 787-794
Zhu, W.; Cai, S.; Cremaschi, L. 2015: Thermal performance and moisture accumulation of fibrous mechanical pipe insulation systems operating at below-ambient temperature in wet conditions with moisture ingress. Science and Technology for the Built Environment 21(6): 862-875
Cao, V.D.; Pilehvar, S.; Salas-Bringas, C.; Szczotok, A.M.; Bui, T.Q.; Carmona, M.; Rodriguez, J.F.; Kjøniksen, A. 2018: Thermal performance and numerical simulation of geopolymer concrete containing different types of thermoregulating materials for passive building applications. Energy and Buildings 173: 678-688
Pashah, S.; Moinuddin, A.; Zubair, S.M. 2016: Thermal performance and optimization of hyperbolic annular fins under dehumidifying operating conditions – analytical and numerical solutions. International Journal of Refrigeration 65: 42-54
Park, S.; Jang, D.; Lee, K. 2016: Thermal performance and orientation effect of an inclined cross-cut cylindrical heat sink for LED light bulbs. International Journal of Heat and Mass Transfer 103: 1371-1377
Xu, H.; Gao, Y.; Li, J.; Wang, H.; Shi, H. 2018: Thermal performance and phase transformation of S-alkylated poly(vinyl chloride) comb-like polymers. Polymer 153: 362-368
Kimpton, H.; Cristaldi, D.A.; Stulz, E.; Zhang, X. 2020: Thermal performance and physicochemical stability of silver nanoprism-based nanofluids for direct solar absorption. Solar Energy 199: 366-376
Liang, Y.; Wu, H.; Huang, G.; Yang, J.; Wang, H. 2017: Thermal performance and service life of vacuum insulation panels with aerogel composite cores. Energy and Buildings 154: 606-617
Li, S.; Kong, L.; Wang, H.; Xu, H.; Li, J.; Shi, H. 2018: Thermal performance and shape-stabilization of comb-like polymeric phase change materials enhanced by octadecylamine-functionalized graphene oxide. Energy Conversion and Management 168: 119-127
Huang, S.; Zhao, J.; Gong, L.; Duan, X. 2017: Thermal performance and structure optimization for slotted microchannel heat sink. Applied Thermal Engineering 115: 1266-1276
Ferdosian, F.; Yuan, Z.; Anderson, M.; Xu, C.C. 2016: Thermal performance and thermal decomposition kinetics of lignin-based epoxy resins. Journal of Analytical and Applied Pyrolysis 119: 124-132
Zhou, H.; Li, Y.; Zuo, Y.; Zhou, M.; Fang, W.; Zhu, Y. 2021: Thermal performance and thermal stress analysis of a 600 MWth solar cylinder external receiver. Renewable Energy 164: 331-345
Deng, J.; Furbo, S.; Kong, W.; Fan, J. 2018: Thermal performance assessment and improvement of a solar domestic hot water tank with PCM in the mantle. Energy and Buildings 172: 10-21
Aghili Yegane, S.P.; Kasaeian, A. 2020: Thermal performance assessment of a flat-plate solar collector considering porous media, hybrid nanofluid and magnetic field effects. Journal of Thermal Analysis and Calorimetry 141(5): 1969-1980
Cuce, P.M. 2017: Thermal performance assessment of a novel liquid desiccant-based evaporative cooling system: An experimental investigation. Energy and Buildings 138: 88-95
Yang, X.; Wang, X.; Liu, Z.; Guo, Z.; Hooman, K. 2021: Thermal performance assessment of a thermal energy storage tank: effect of aspect ratio and tilted angle. International Journal of Energy Research 45(7): 11157-11178
Tyagi, V.; Pandey, A.; Buddhi, D.; Kothari, R. 2016: Thermal performance assessment of encapsulated PCM based thermal management system to reduce peak energy demand in buildings. Energy and Buildings 117: 44-52
Cascone, S.; Gagliano, A.; Poli, T.; Sciuto, G. 2018: Thermal performance assessment of extensive green roofs investigating realistic vegetation-substrate configurations. Building Simulation 12(3): 379-393
Leitão, D.; Barbosa, J.; Soares, E.; Miranda, T.; Cristelo, N.; Briga-Sá, A. 2017: Thermal performance assessment of masonry made of ICEB's stabilised with alkali-activated fly ash. Energy and Buildings 139: 44-52
Ramakrishnan, S.; Wang, X.; Sanjayan, J.; Wilson, J. 2017: Thermal performance assessment of phase change material integrated cementitious composites in buildings: Experimental and numerical approach. Applied Energy 207: 654-664
Poongavanam, G.K.; Sakthivadivel, D.; Meikandan, M.; Balaji, K.; Vigneswaran, V.S. 2019: Thermal performance augmentation of a solar flat plate collector using the shot peening technique. Science and Technology for the Built Environment 26(3): 437-445
Cheng, H.; Ju, Y.; Fu, Y. 2019: Thermal performance calculation with heat transfer correlations and numerical simulation analysis for typical LNG open rack vaporizer. Applied Thermal Engineering 149: 1069-1079
Wu, S.; Laurent, T.D.C.; Abubakar, S.; Li, Y. 2021: Thermal performance characteristics of a micro-combustor with swirl rib fueled with premixed hydrogen/air. International Journal of Hydrogen Energy 46(73): 36503-36514
Jang, D.S.; Chung, H.J.; Jeon, Y.; Kim, Y. 2018: Thermal performance characteristics of a pulsating heat pipe at various nonuniform heating conditions. International Journal of Heat and Mass Transfer 126: 855-863
Sun, K.; Tien, C. 1975: Thermal performance characteristics of heat pipes. International Journal of Heat and Mass Transfer 18(3): 363-380
Imtiaz Hussain, M.; Lee, G.H. 2016: Thermal performance comparison of line- and point-focus solar concentrating systems: Experimental and numerical analyses. Solar Energy 133: 44-54
Qu, J.; Li, X.; Xu, Q.; Wang, Q. 2017: Thermal performance comparison of oscillating heat pipes with and without helical micro-grooves. Heat and Mass Transfer 53(11): 3383-3390
Nowakowski, A.J.; Peaden, J.M.; Tuberville, T.D.; Buhlmann, K.A.; Todd, B.D. 2020: Thermal performance curves based on field movements reveal context-dependence of thermal traits in a desert ectotherm. Landscape Ecology 35(4): 893-906
Ruan, Y.; Yan, N.; Zhu, H.; Zhou, K.; Wei, B. 2017: Thermal performance determination of binary Fe-Al alloys at elevated temperatures. Journal of Alloys and Compounds 701: 676-681
Hosseinirad, E.; Hormozi, F. 2018: Thermal performance enhancement in a miniature channel using different passive methods. Journal of Thermal Analysis and Calorimetry 135(3): 1849-1861
Hussain, S.; Liu, J.; Wang, L.; Sunden, B.A. 2019: Thermal performance enhancement in a wedge duct with in-line pin fins combined with vortex generators. International Journal of Numerical Methods for Heat-Fluid Flow 29(8): 2545-2565
Hussein, O.A.; Habib, K.; Muhsan, A.S.; Saidur, R.; Alawi, O.A.; Ibrahim, T.K. 2020: Thermal performance enhancement of a flat plate solar collector using hybrid nanofluid. Solar Energy 204: 208-222
Jeon, J.; Park, J.H.; Wi, S.; Kim, K.; Kim, S. 2019: Thermal performance enhancement of a phase change material with expanded graphite via ultrasonication. Journal of Industrial and Engineering Chemistry 79: 437-442
Iranmanesh, S.; Ong, H.C.; Ang, B.C.; Sadeghinezhad, E.; Esmaeilzadeh, A.; Mehrali, M. 2017: Thermal performance enhancement of an evacuated tube solar collector using graphene nanoplatelets nanofluid. Journal of Cleaner Production 162: 121-129
Xiong, T.; Shah, K.W.; Kua, H.W. 2021: Thermal performance enhancement of cementitious composite containing polystyrene/n-octadecane microcapsules: An experimental and numerical study. Renewable Energy 169: 335-357
Zou, D.; Ma, X.; Liu, X.; Zheng, P.; Hu, Y. 2018: Thermal performance enhancement of composite phase change materials (PCM) using graphene and carbon nanotubes as additives for the potential application in lithium-ion power battery. International Journal of Heat and Mass Transfer 120: 33-41
Kazmi, S.M.S.; Munir, M.J.; Patnaikuni, I.; Wu, Y.; Fawad, U. 2018: Thermal performance enhancement of eco-friendly bricks incorporating agro-wastes. Energy and Buildings 158: 1117-1129
Al-Mudhafar, A.H.; Nowakowski, A.F.; Nicolleau, F.C. 2018: Thermal performance enhancement of energy storage systems via phase change materials utilising an innovative webbed tube heat exchanger. Energy Procedia 151: 57-61
Hu, Y.; Cheng, J.; Zhang, W.; Shirakashi, R.; Wang, S. 2013: Thermal performance enhancement of grooved heat pipes with inner surface treatment. International Journal of Heat and Mass Transfer 67: 416-419
Law, W.P.; Gimbun, J. 2019: Thermal performance enhancement of non-premixed syngas combustion in a partial combustion unit by winged nozzle: Experimental and CFD study. Energy 182: 148-158
Acurio, K.; Chico-Proano, A.; Martínez-Gómez, J.; Ávila, C.F.; Ávila, .; Orozco, M. 2018: Thermal performance enhancement of organic phase change materials using spent diatomite from the palm oil bleaching process as support. Construction and Building Materials 192: 633-642
Sudhakar, P.; Cheralathan, M. 2019: Thermal performance enhancement of solar air collector using a novel V-groove absorber plate with pin-fins for drying agricultural products: an experimental study. Journal of Thermal Analysis and Calorimetry 140(5): 2397-2408
Sözen, A.; Şirin, C.; Khanlari, A.; Tuncer, A.D.; Gürbüz, E.Y. 2020: Thermal performance enhancement of tube-type alternative indirect solar dryer with iron mesh modification. Solar Energy 207: 1269-1281
Wiriyasart, S.; Naphon, P. 2018: Thermal performance enhancement of vapor chamber by coating mini-channel heat sink with porous sintering media. International Journal of Heat and Mass Transfer 126: 116-122
Lucchi, E.; Becherini, F.; Di Tuccio, M.C.; Troi, A.; Frick, J.; Roberti, F.; Hermann, C.; Fairnington, I.; Mezzasalma, G.; Pockelé, L.; Bernardi, A. 2017: Thermal performance evaluation and comfort assessment of advanced aerogel as blown-in insulation for historic buildings. Building and Environment 122: 258-268
Alrashidi, H.; Issa, W.; Sellami, N.; Sundaram, S.; Mallick, T. 2022: Thermal performance evaluation and energy saving potential of semi-transparent Cd Te in Façade BIPV. Solar Energy 232: 84-91
Kim, M.; Lee, S.; Yoon, S.; Go, G. 2016: Thermal performance evaluation and parametric study of a horizontal ground heat exchanger. Geothermics 60: 134-143
Abdelrazek, A.H.; Alawi, O.A.; Kazi, S.; Yusoff, N. 2021: Thermal performance evaluation for alumina coated MWCNTs composite nanofluid in annular passage of various eccentricities. Powder Technology 391: 114-132
Jeong, S.; Lee, J.; Seo, J.; Kim, S. 2014: Thermal performance evaluation of Bio-based shape stabilized PCM with boron nitride for energy saving. International Journal of Heat and Mass Transfer 71: 245-250
Brewer, R.A.; Saydah, A.R.; Nestler, D.E.; Florence, D.E. 1973: Thermal performance evaluation of REi panel gaps for Space Shuttle Orbiter. Journal of Spacecraft and Rockets 10(1): 23-28
Aly, W.I.; Elbalshouny, M.A.; Abd El-Hameed, H.; Fatouh, M. 2017: Thermal performance evaluation of a helically-micro-grooved heat pipe working with water and aqueous Al 2 O 3 nanofluid at different inclination angle and filling ratio. Applied Thermal Engineering 110: 1294-1304
Kiran Kumar, D.; Puranik, S. 2016: Thermal performance evaluation of a mineral-based cement tile as roofing material. Indoor and Built Environment 26(3): 409-421
Jouybari, H.J.; Nimvari, M.E.; Saedodin, S. 2019: Thermal performance evaluation of a nanofluid‐based flat‐plate solar collector. Journal of Thermal Analysis and Calorimetry 137(5): 1757-1774
Qin, D.; Yu, Z.(.; Yang, T.; Li, S.; Zhang, G. 2019: Thermal performance evaluation of a new structure hot water tank integrated with phase change materials. Energy Procedia 158: 5034-5040
He, Y.; Yu, H.; Chen, P.; Zhao, M. 2018: Thermal performance evaluation of a new type of green roof system. Energy Procedia 152: 384-389
Torres-Rodríguez, A.; Morillón-Gálvez, D.; Aldama-Ávalos, D.; Hernández-Gómez, V.H.; García Kerdan, I. 2020: Thermal performance evaluation of a passive building wall with CO2-filled transparent thermal insulation and paraffin-based PCM. Solar Energy 205: 1-11
Abdou, O.A.; Murali, K.; Morsi, A. 1996: Thermal performance evaluation of a prefabricated fiber-reinforced plastic building envelope system. Energy and Buildings 24(1): 77-83
Lee, C. 2019: Thermal performance evaluation of a vertical closed-loop ground heat exchanger according to rock type in Korea. Energy and Buildings 183: 184-194
Hatami, M.; Mosayebidorcheh, S.; Jing, D. 2017: Thermal performance evaluation of alumina-water nanofluid in an inclined direct absorption solar collector (IDASC) using numerical method. Journal of Molecular Liquids 231: 632-639
Ren, H.; Lin, W.; Ma, Z.; Fan, W.; Wang, X. 2017: Thermal performance evaluation of an integrated photovoltaic thermal-phase change material system using Taguchi method. Energy Procedia 121: 118-125
Pandey, A.K.; Tyagi, V.V.; Rahim, N.A.; Kaushik, S.C.; Tyagi, S.K. 2015: Thermal performance evaluation of direct flow solar water heating system using exergetic approach. Journal of Thermal Analysis and Calorimetry 121(3): 1365-1373
Kazmi, S.M.S.; Munir, M.J.; Wu, Y.; Hanif, A.; Patnaikuni, I. 2018: Thermal performance evaluation of eco-friendly bricks incorporating waste glass sludge. Journal of Cleaner Production 172: 1867-1880
Chang, S.J.; Wi, S.; Jeong, S.; Kim, S. 2016: Thermal performance evaluation of macro-packed phase change materials (PCMs) using heat transfer analysis device. Energy and Buildings 117: 120-127
Kanikzadeh, M.; Sohankar, A. 2016: Thermal performance evaluation of the rotating U-shaped micro/mini/macrochannels using water and nanofluids. Numerical Heat Transfer, Part A: Applications 70(6): 650-672
Chowdhury, D.; Neogi, S. 2019: Thermal performance evaluation of traditional walls and roof used in tropical climate using guarded hot box. Construction and Building Materials 218: 73-89
Gomaa, M.; Carfrae, J.; Goodhew, S.; Jabi, W.; Veliz Reyes, A. 2019: Thermal performance exploration of 3D printed cob. Architectural Science Review 62(3): 230-237
Yoon, Y.; Park, S.; Kim, D.R.; Lee, K. 2018: Thermal performance improvement based on the partial heating position of a heat sink. International Journal of Heat and Mass Transfer 124: 752-760
Chang, S.W.; Huang, B. 2013: Thermal performance improvement by injecting air into water flow. International Journal of Heat and Mass Transfer 57(2): 439-456
Khodabandeh, E.; Rozati, S.A.; Joshaghani, M.; Akbari, O.A.; Akbari, S.; Toghraie, D. 2018: Thermal performance improvement in water nanofluid/GNP–SDBS in novel design of double-layer microchannel heat sink with sinusoidal cavities and rectangular ribs. Journal of Thermal Analysis and Calorimetry 136(3): 1333-1345
Choi, Y.; Mae, M.; Bae Kim, H. 2019: Thermal performance improvement method for air-based solar heating systems. Solar Energy 186: 277-290
Gao, Y.; Fan, R.; Li, H.; Liu, R.; Lin, X.; Guo, H.; Gao, Y. 2016: Thermal performance improvement of a horizontal ground-coupled heat exchanger by rainwater harvest. Energy and Buildings 110: 302-313
Park, S.; Jang, D.; Lee, K. 2015: Thermal performance improvement of a radial heat sink with a hollow cylinder for LED downlight applications. International Journal of Heat and Mass Transfer 89: 1184-1189
Chamoli, S.; Lu, R.; Xu, D.; Yu, P. 2018: Thermal performance improvement of a solar air heater fitted with winglet vortex generators. Solar Energy 159: 966-983
Sözen, A.; Kazancıoğlu, F..; Tuncer, A.D.; Khanlari, A.; Bilge, Y.C.; Gungor, A. 2021: Thermal performance improvement of an indirect solar dryer with tube-type absorber packed with aluminum wool. Solar Energy 217: 328-341
Njoku, H.O.; Agbo, I.N.; Agwuna, I.P.; Egeonu, D.I.; Asuquo, F.U.; Arji, E.I. 2018: Thermal performance improvement of kerosene cook-stoves by heat reuse and radiant heat shielding. Journal of Thermal Analysis and Calorimetry 136(4): 1847-1860
Rajabi, M.; Mousavi G., S. 2019: Thermal performance improvement of magnetic-shield superconducting fault current Limiter, by using heat-sink in its structure. Physica C: Superconductivity and its Applications 556: 30-35
Wu, S.; Abubakar, S.; Li, Y. 2021: Thermal performance improvement of premixed hydrogen/air fueled cylindrical micro-combustor using a preheater-conductor plate. International Journal of Hydrogen Energy 46(5): 4496-4506
Chang, S.; Lin, C. 2013: Thermal performance improvement with scale imprints over boiling surface of two-phase loop thermosyphon at sub-atmospheric conditions. International Journal of Heat and Mass Transfer 56(1-2): 294-308