The impact of soil depth on land surface energy and water fluxes in the North American Monsoon region

This study explores the influence of variable soil depths on simulated land?atmosphere exchanges from a currently operational land surface model over the North American Monsoon (NAM) region of southwestern North America. It is shown that the neglect of observed (actual) soil depths can limit land surface model performance at the sites studied. The main impact of accounting for shallower soil depths is to increase the dispersion, (i.e. the dynamic range) of sensible and latent heat fluxes when compared with simulations using a common fixed soil column depth of 2 meters. It is also shown that accounting for local soil depth variability can, moderately, improve land surface model flux estimation as compared with tower...

Categories: Publication; Types: Citation, Journal Citation; Tags: Journal of Arid Environments, evaporation, land surface models, micrometeorology, north american monsoon, All tags... soil depth, Fewer tags

Canopy structure and atmospheric flows in relation to the δ13C of respired CO2 in a subalpine coniferous forest

Stable isotopes provide insight into ecosystem carbon cycling, plant physiological processes, atmospheric boundary-layer dynamics, and are useful for the integration of processes over multiple scales. Of particular interest is the carbon isotope content (δ13C) of nocturnal ecosystem-respired CO2 (δR). Recent advances in technology have made it possible to continuously examine the variation in δR within a forest canopy over relatively long time-scales (months–years). We used tunable diode laser spectroscopy to examine δR at within- and below-canopy spatial locations in a Colorado subalpine forest (the Niwot Ridge AmeriFlux site). We found a systematic pattern of increased δR within the forest canopy (δR-c) compared...

Categories: Publication; Types: Citation; Tags: Drainage flow, Humidity, Micrometeorology, Soil moist

Modeling temperature and humidity profiles within forest canopies

Abstract (from http://www.sciencedirect.com/science/article/pii/S0168192315002142): Physically-based models are a powerful tool to help understand interactions of vegetation, atmospheric dynamics, and hydrology, and to test hypotheses regarding the effects of land cover, management, hydrometeorology, and climate variability on ecosystem processes. The purpose of this paper is to evaluate recent modifications and further refinements to a multi-layer plant canopy model for simulating temperature and water vapor within three diverse forest canopies: a 4.5-m tall aspen thicket, a 15-m tall aspen canopy, and a 60-m tall Douglas fir canopy. Performance of the model was strongly related to source strength and profile stability...

Categories: Publication; Types: Citation; Tags: Drought, Drought, Fire and Extreme Weather, Fire, Forest canopy, Forests, All tags... Landscapes, Micrometeorology, Multi-layer canopy model, Northwest CASC, Plants, SHAW model, Wildlife and Plants, Fewer tags