Abstract
BACKGROUND: Existing research provides estimates of the biophysical potential for increasing soil organic carbon (SOC) stock, however additional research is needed to enhance our understanding of the economic potential for agricultural soils to offset or help reduce CO(2) emissions. This study derives the marginal cost to increase SOC sequestration by combining SOC sequestration potential estimates developed using the Intergovernmental Panel on Climate Change (IPCC) factors with an existing payment scheme that was designed to increase no-till (NT) adoption on U.S. cropland. The marginal costs of increasing SOC is a function of the amount of SOC that could be increased through NT and the expected cost to landowners of changing management to use NT. RESULTS: The variability in SOC sequestration rates due to different land-use, management histories, climate, and soils, combined with the 48 unique payment rates to adopt NT, yield over 5,000 unique marginal cost values for increasing SOC sequestration. Nearly 95 percent of the biophysical potential SOC sequestration increase on U.S. cropland (2802 Tg CO(2) from 140.1 Tg CO(2) year(-1) for 20 years) could be captured for less than $100 Mg(-1) CO(2.) An estimated 64 to 93 percent of the biophysical potential could be captured for less than the low and high estimated costs to capture CO(2) for geologic storage of $36.36 to $86.06 Mg(-1) CO(2), respectively. CONCLUSIONS: Decreasing tillage intensity through adoption of no-till agriculture offers a cost-effective way to offset a portion of increasing global CO(2) emissions. This research demonstrates that increasing SOC stocks through NT adoption can offset CO(2) emissions at a lower cost than some other options for preventing CO(2) from entering the atmosphere.