142-3Contribution of a Perennial Forage Grass to Carbon Storage in a Peanut-Cotton-Bahia Rotation in Ultisols.
See more from this Division: S06 Soil & Water Management & ConservationSee more from this Session: Agricultural Management Practices Impact On Soil Carbon and Nitrogen Pools and Soil Quality Dynamics: II
Monday, October 22, 2012
Duke Energy Convention Center, Exhibit Hall AB, Level 1
The traditional cropping system in the Southeast US is an annual rotation of cotton and peanuts under conventional tillage. This cropping system contributes to erosion and loss of nutrients in the soils of this region. Incorporation of perennial grasses (e.g., bahiagrass) to this rotation has been suggested to improve soil organic carbon (SOC), particularly in conjunction with conservation tillage practices. In addition, grazing by livestock provides another mechanism to maintain and recycle SOC and nutrients. In order to determine the effect of perennial grasses and grazing activities on carbon sequestration in a peanut-cotton rotation, total SOC and its isotopic composition were evaluated on established (>10 years) crop rotation systems. Systems evaluated included 1) peanut-cotton under conventional tillage, 2) peanut-cotton under strip tillage, 3) peanut-cotton-bahia-bahia under conventional tillage, 4) peanut-cotton-bahia under strip tillage and 5) peanut-cotton-bahia-bahia rotation under strip tillage with cattle grazing. The isotopic ratio of 13C/12C was evaluated to assess the contribution of the perennial grass to SOC. Plants with a C4 photosynthetic pathway (e.g., bahia) are known to have greater 13C/12C ratio and higher d13C-values (-19 to -9‰) than C3 plants (e.g., peanut, cotton, oat and rye) (-35 to -20‰). Results indicated that approximately 35% of the SOC was due to bahia, compared to <5% in systems without bahia. The δ13C values in the 0-5 cm depth were highest following 2 years of bahia and lowest at the onset of the first year of bahia indicating that this pool of C is cycling. Higher δ13C values were observed for the rotation with bahia, to a depth of 15-30 cm. Use of a moldboard plow increased δ13C compared to strip tilled, but cattle grazing had no effect on δ13C values. Results suggest that bahia is relatively labile and concentrated near the surface.
See more from this Division: S06 Soil & Water Management & ConservationSee more from this Session: Agricultural Management Practices Impact On Soil Carbon and Nitrogen Pools and Soil Quality Dynamics: II