L. Chris Kiser, Virginia Polytechnic Institute and State University, 305 Cheatham Hall (0324), Blacksburg, VA 24061, J. Michael Kelly, 324 Cheatham Hall, Virginia Tech, Virginia Tech University, College of Natural Resources, Blacksburg, VA 24061, and Paul Mays, Tennesee Valley Authority (TVA), 5117 Foxwood Road, Knoxville, TN 37921.
Increases in atmospheric C have resulted in concerns about global warming and interest in finding means to sequester atmospheric C through land management strategies. The purpose of this study was to (i) compare changes in mineral soil C over a 30-year interval and (ii) examine the role of mineral soil N forms and topography in these changes. Soil samples were collected at permanently identified points on the Camp Branch Watershed, a second growth oak forest on the Cumberland Plateau in central
Tennessee, in July of 1976 and archived. These points were re-sampled in July of 2006 and both archived and new samples of the 0 to 10 cm increment of the mineral soil were analyzed for C and N using the same procedures. Paired comparisons revealed changes in C and N concentration and mass were distinct to each soil series. Changes in C concentration ranged from -13.1% to +12.0%. Changes in C mass ranged from -11.3% to +8.3%. Increases in C were most closely associated with increases in the C/total-N ratio. Mineral soil N forms and C/N ratios explained 98.5% of variation in C in 1976 and 95.9% in 2006. Regression analyses predicted upland sites to accumulate +83% more C than cove sites. However, since topography explained <20% of variation in mineral soil N forms and C/N ratios in both years, we hypothesize that species composition and stand age were additional factors influencing mineral soil C storage.