Recent trends in the near-surface climatology of the northern North American Great Plains
Bromley, G. T., Gerken, T., Prein, A. F., & Stoy, P. C. (2020). Recent trends in the near-surface climatology of the northern North American Great Plains. Journal Of Climate, 33, 461-475. doi:10.1175/JCLI-D-19-0106.1
We examined climate trends in the northern North American Great Plains (NNAGP) from 1970 to 2015, a period that aligns with widespread land-use changes in this globally important agricultural region. Trends were calculated from the Climatic Research Unit (CRU) and other climate datasets using a l... Show moreWe examined climate trends in the northern North American Great Plains (NNAGP) from 1970 to 2015, a period that aligns with widespread land-use changes in this globally important agricultural region. Trends were calculated from the Climatic Research Unit (CRU) and other climate datasets using a linear regression model that accounts for temporal autocorrelation. The NNAGP warmed on an annual basis, with the largest change occurring in winter (DJF) at 0.4 degrees C decade(-1). January in particular warmed at nearly 0.9 degrees C decade(-1). The NNAGP cooled by -0.18 degrees C decade(-1) during May and June, nearly the opposite of global warming trends during the study period. The atmospheric vapor pressure deficit (VPD), which can limit crop growth, decreased in excess of -0.4 hPa decade(-1) during climatological summer in the southeastern part of the study domain. Precipitation P increased in the eastern portion of the NNAGP during all seasons except fall and increased during May and June in excess of 8 mm decade(-1). Climate trends in the NNAGP largely followed global trends except during the early warm season (May and June) during which 2-m air temperature T-air became cooler, VPD lower, and P greater across large parts of the study region. These changes are consistent with observed agricultural intensification during the study period, namely the reduction of summer fallow and expansion of agricultural land use. Global climate model simulations indicate that observed T-air trends cannot be explained by natural climate variability. However, further climate attribution experiments are necessary to understand if observed changes are caused by increased agricultural intensity or other factors. Show less