Impacts of Land–Atmosphere Feedbacks on Deep, Moist Convection on the Canadian Prairies

• Published in: Earth interactions Vol. 15; no. 31; pp. 1 - 29
• Main Authors: Brimelow, Julian C, Hanesiak, John M, Burrows, William R
• Format: Journal Article
• Language: English
• Published: Washington American Meteorological Society 01.10.2011
• Subjects: Anomalies; Atmosphere; Atmospheric convection; Boundary layers; Convection; Drought; Duration; Heat flux; Heat transfer; Land; Latent heat; Lifting condensation level; Lightning; Lightning activity; Meteorology; Mixed layer; Moist convection; Moisture effects; Normalized difference vegetative index; Prairies; Precipitation; Radiation; Rain; Rawinsondes; Remote observing; Remote sensing; Sensible and latent heat; Soil moisture; Storms; Thunderstorm activity; Thunderstorms; Vegetation; Vegetation index; United States > US; North America; Great Plains; Alberta Canada; Canada
• ISSN: 1087-3562; 1087-3562
• DOI: 10.1175/2011EI407.1

Abstract The purpose of this study was to focus on how anomalies in the normalized difference vegetation index (NDVI; a proxy for soil moisture) over the Canadian Prairies can condition the convective boundary layer (CBL) so as to inhibit or facilitate thunderstorm activity while also considering the role of synoptic-scale forcing. This study focused on a census agricultural region (CAR) over central Alberta for which we had observed lightning data (proxy for thunderstorms), remotely sensed NDVI data, and in situ rawinsonde data (to quantify impacts of vegetation vigor on the CBL characteristics) for 11 summers from 1999 to 2009. The authors’ data suggest that the occurrence of lightning over the study area is more likely (and is of longer duration) when storms develop in an environment in which the surface and upper-air synoptic-scale forcing are synchronized. On days when surface forcing and midtropospheric ascent are present, storms are more likely to be triggered when NDVI is much above average, compared to when NDVI is much below average. Additionally, the authors found the response of thunderstorm duration to NDVI anomalies to be asymmetric. That is, the response of lightning duration to anomalies in NDVI is marked when NDVI is below average but is not necessarily discernible when NDVI is above average. The authors propose a conceptual model, based largely on observations, that integrates all of the above findings to describe how a reduction in vegetation vigor—in response to soil moisture deficits—modulates the partitioning of available energy into sensible and latent heat fluxes at the surface, thereby modulating lifting condensation level heights, which in turn affect lightning activity.