Influence of C 4 vegetation on 13 CO 2 discrimination and isoforcing in the upper Midwest, United States

Agricultural crops with a C 4 photosynthetic pathway rapidly expanded across North America as early as 800 A.D. Their distribution continues to expand globally as demands for food and biofuel production increase. These systems are highly productive, having a significant impact on carbon and water exchange between the land and atmosphere. Here, we investigate the relative impact of agricultural C 4 vegetation on the 13 CO 2 photosynthetic discrimination and atmospheric isotopic forcing in the upper Midwest, United States. We address three questions: (1) What is the relative importance of C 3 and C 4 species to the CO 2 budget? (2) How do these different photosynthetic pathways influence the photosynthetic discrimination within this heterogeneous landscape? (3) To what extent does land use change (i.e., a change in C 4 crops) impact atmospheric isotopic forcing and the isotopic signature of the atmosphere? These questions are addressed using measurements obtained from the University of Minnesota tall tower (244 m) trace gas observatory (TGO) over the growing seasons of 2007 and 2008 and are supported with scaled‐up values of discrimination and isotopic forcing based on ecosystem‐scale eddy flux observations and high‐resolution land use data. Our land use analyses indicate that local and regional C 4 production was higher by 10% in 2007 due to increased demand for biofuel. The 2007 growing season was also characterized by moderate drought as a consequence of low antecedent soil water content. Isotopic flux ratio measurements from TGO provide evidence that the increase in C 4 land use and drier soil conditions of 2007 had a significant impact on the growing season 13 CO 2 photosynthetic discrimination, which ranged from 11.5 to 14.8 in 2007 and 12.4‰ to 17.4‰ in 2008. Isotopic partitioning indicated that C 4 species accounted for about 20 to 40% of the growing season gross photosynthetic CO 2 exchange. The isoforcing analysis revealed that C 3 discrimination dominated the atmospheric δ a 13 budget, especially during spring and fall. Estimates of 13 CO 2 photosynthetic discrimination for this region support recently published isotope modeling studies that explicitly accounted for increases in C 4 cropland, which has significant implications for estimating the terrestrial carbon sink strength based on inverse modeling techniques.