Soil organic carbon sequestration potential and policy optimization

Land management could help mitigate climate change by sequestering atmospheric carbon dioxide as soil organic carbon (SOC). The impact of a given management change on the SOC content of a given volume of soil is generally unknown, but is likely moderated by features of the land that collectively determine its sequestration potential. To maximize sequestration, management interventions should be preferentially applied to fields with the highest sequestration potential and the lowest cost of application. We present a design-based statistical framework for estimating sequestration potential, average treatment effects, and optimal management policies from a randomized experiment with baseline covariate information. We review the myriad and nested sources of uncertainty that arise in this context and formalize the problem using potential outcomes. We show that a particular regression estimator -- regressing field-level SOC on management indicators and their interactions with covariates -- can help identify effective policies. The regression estimator also gives asymptotically valid inference on average treatment effects under the randomized design -- without modeling assumptions -- and can increase precision and power compared to the difference-in-means $T$-test. We conclude by discussing the saturation hypothesis in relation to sequestration potential, other study designs including observational studies of SOC, models for policy costs, nonparametric inference, and broader policy uncertainties.