ABSTRACT:

Vapor pressure deficit (VPD) is a critical variable in assessing drought conditions and evaluating plant water stress. Gridded products of global and regional VPD are not freely available from satellite remote sensing, model reanalysis, or ground observation datasets. We present two versions of the first gridded VPD product for the Continental US and parts of Northern Mexico and Southern Canada (CONUS+) at a 1 km spatial resolution and daily time step. We derived VPD from Daymet maximum daily temperature and average daily vapor pressure and scale the estimates based on (1) climate determined by the Köppen-Geiger classifications and (2) land cover determined by the International Geosphere-Biosphere Programme. Ground-based VPD data from 253 AmeriFlux sites representing different climate and land cover classifications were used to improve the Daymet-derived VPD estimates for every pixel in the CONUS+ grid to produce the final datasets. We evaluated the Daymet-derived VPD against independent observations and reanalysis data. The CONUS+ VPD datasets will aid in investigating disturbances including drought and wildfire, and informing land management strategies.

ABSTRACT:

We use a land surface hydrology model with a predictive phenology model to analyze changes in how vegetation and the atmosphere interact during extreme drought events known as flash droughts. Included here are model results accompanying a manuscript to be submitted to a journal for peer review. The model outputs include soil moisture, root water uptake, evapotranspiration, gross primary productivity, stomatal conductance, infiltration, leaf area index, and the fraction of photosynthetically active radiation. We find that plants nearly halt water and carbon exchanges and limit their growth during flash drought.