Modelling sub-canopy incoming longwave radiation to seasonal snow using air and tree trunk temperatures

Webster, Clare, Rutter, Nick, Zahner, Franziska and Jonas, Tobias (2016) Modelling sub-canopy incoming longwave radiation to seasonal snow using air and tree trunk temperatures. Journal of Geophysical Research - Atmospheres, 121 (3). pp. 1220-1235. ISSN 2169-8996

[img]
Preview
Text
Webster_et_al-2015-JGRA.pdf - Published Version

Download (5MB) | Preview
Official URL: http://dx.doi.org/10.1002/2015JD024099

Abstract

Data collected at three Swiss alpine forested sites over a combined eleven-year period were used to evaluate the role of air temperature in modeling sub-canopy incoming longwave radiation to the snow surface. Simulated sub-canopy incoming longwave radiation is traditionally partitioned into that from the sky and that from the canopy, i.e. a two-part model. Initial uncertainties in predicting longwave radiation using the two-part model resulted from vertical differences in measured air temperature. Above-canopy (35m) air temperatures were higher than those within (10m) and below (2m) canopy throughout four snow seasons (Dec-Apr), demonstrating how the forest canopy can act as a cold sink for air.
Lowest model RMSE was using above-canopy air temperature. Further investigation of modeling sub-canopy longwave radiation using above-canopy air temperature showed underestimations, particularly during periods of high insolation. In order to explicitly account for canopy temperatures in modeling longwave radiation, the two-part model was improved by incorporating a measured trunk-view component and trunk temperature. Trunk temperature measurements were up to 25°C higher than locally measured air temperatures. This three-part model reduced the RMSE by up to 7.7 Wm-2 from the two-part air temperature model at all sensor positions across the 2014 snowmelt season, and performed particularly well during periods of high insolation when errors from the two-part model were up to 40 Wm-2. A parameterization predicting tree trunk temperatures using measured air temperature and incoming shortwave radiation demonstrate a simple method that can be applied to provide input to the three-part model across mid-latitude coniferous forests.

Item Type: Article
Uncontrolled Keywords: canopy radiative transfer; longwave radiation; forest temperature; coniferous forest; hemispherical photography
Subjects: F800 Physical and Terrestrial Geographical and Environmental Sciences
Department: Faculties > Engineering and Environment > Geography and Environmental Sciences
Depositing User: Nick Rutter
Date Deposited: 09 Feb 2016 09:52
Last Modified: 01 Aug 2021 01:32
URI: http://nrl.northumbria.ac.uk/id/eprint/25914

Actions (login required)

View Item View Item

Downloads

Downloads per month over past year

View more statistics