Soil change and loblolly pine (Pinus taeda) seedling growth following site preparation tillage in the Upper Coastal Plain of the southeastern United States

Lincoln, M.C.; Will, R.E.; Morris, L.A.; Carter, E.A.; Markewitz, D.; Britt, J.R.; Cazell, B.; Ford, V.

Forest Ecology and Management 242(2/3): 558-568

2007


ISSN/ISBN: 0378-1127
DOI: 10.1016/j.foreco.2007.01.069
Accession: 013064550

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Abstract
To determine the relationship between changes in soil physical properties due to tillage and growth of loblolly pine (Pinus taeda L.) seedlings, we measured soil moisture and penetration resistance for a range of tillage treatments on two Upper Coastal Plain sites in Georgia and correlated these measurements to the growth of individual seedlings. The five tillage treatments were: no-till (NT), coulter only (C), coulter + subsoil (CS), coulter + bed (CB), and coulter + subsoil + bed (CSB). The effects of tillage on soil penetration resistance and volumetric water content were isolated from the potentially confounding effects of tillage on competition and soil fertility by completely eliminating all competing vegetation and by comparing tree response with and without periodic nutrient additions. At the site with a clay B-horizon at the surface, the tillage treatments increased relative height and relative diameter growth compared to the NT treatment during the first season, decreased soil penetration resistance, and decreased volumetric soil moisture (VWC). At the sandy site with a loamy sand topsoil averaging 15-40 cm, in depth over a sandy clay loam B-horizon, bedding, subsoiling and the minimal tillage associated with machine planting increased seedling growth compared to the C treatment. Soil penetration resistance and VWC were greatest in the C treatment, intermediate in the NT treatment, and lowest in the treatments receiving bedding. Soil penetration resistance between 40 and 50 cm (p = 0.03, r(2) = 0.40) was negatively correlated with seedling relative diameter growth at the clay site. Soil penetration resistance between 10 and 40 cm (p < 0.02, r(2) = 0.35) was negatively correlated with seedling diameters at the sandy site. Overall, the positive effects of soil tillage on growth were relatively small (i.e., increases in height and diameter of about 20%). Most of the positive benefits of tillage on growth and soil physical properties were captured with less intensive treatments such as machine planting (sandy site) or the coulter only (clay site).