Editorial Type:
Article
Article Type:
Research Article

Heat Balance in the Nocturnal Boundary Layer during CASES-99

Jielun Sun National Center for Atmospheric Research,+ Boulder, Colorado

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Sean P. Burns National Center for Atmospheric Research,+ Boulder, Colorado

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Anthony C. Delany National Center for Atmospheric Research,+ Boulder, Colorado

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Steven P. Oncley National Center for Atmospheric Research,+ Boulder, Colorado

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Thomas W. Horst National Center for Atmospheric Research,+ Boulder, Colorado

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Donald H. Lenschow National Center for Atmospheric Research,+ Boulder, Colorado

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Print Publication:
01 Nov 2003
DOI:
https://doi.org/10.1175/1520-0450(2003)042<1649:HBITNB>2.0.CO;2
Page(s):
1649–1666
Restricted access

Abstract

A unique set of nocturnal longwave radiative and sensible heat flux divergences was obtained during the 1999 Cooperative Atmosphere–Surface Exchange Study (CASES-99). These divergences are based on upward and downward longwave radiation measurements at two levels and turbulent eddy correlation measurements at eight levels. In contrast to previous radiation divergence measurements obtained within 10 m above the ground, radiative flux divergence was measured within a deeper layer—between 2 and 48 m. Within the layer, the radiative flux divergence is, on average, comparable to or smaller than the sensible heat flux divergence. The horizontal and vertical temperature advection, derived as the residual in the heat balance using observed sensible heat and radiative fluxes, are found to be significant terms in the heat balance at night. The observations also indicate that the radiative flux divergence between 2 and 48 m was typically largest in the early evening. Its magnitude depends on how fast the ground cools and on how large the vertical temperature gradient is within the layer. A radiative flux difference of more than 10 W m−2 over 46 m of height was observed under weak-wind and clear-sky conditions after hot days. Wind speed variation can change not only the sensible heat transfer but also the surface longwave radiation because of variations of the area exposure of the warmer grass stems and soil surfaces versus the cooler grass blade tips, leading to fluctuations of the radiative flux divergence throughout the night.

Additional affiliation: Program in Atmospheric and Oceanic Sciences, University of Colorado, Boulder, Colorado

Corresponding author address: Jielun Sun, National Center for Atmospheric Research, 3450 Mitchell Lane, P.O. Box 3000, Boulder, CO 80307-3000. jsun@ucar.edu

Abstract

A unique set of nocturnal longwave radiative and sensible heat flux divergences was obtained during the 1999 Cooperative Atmosphere–Surface Exchange Study (CASES-99). These divergences are based on upward and downward longwave radiation measurements at two levels and turbulent eddy correlation measurements at eight levels. In contrast to previous radiation divergence measurements obtained within 10 m above the ground, radiative flux divergence was measured within a deeper layer—between 2 and 48 m. Within the layer, the radiative flux divergence is, on average, comparable to or smaller than the sensible heat flux divergence. The horizontal and vertical temperature advection, derived as the residual in the heat balance using observed sensible heat and radiative fluxes, are found to be significant terms in the heat balance at night. The observations also indicate that the radiative flux divergence between 2 and 48 m was typically largest in the early evening. Its magnitude depends on how fast the ground cools and on how large the vertical temperature gradient is within the layer. A radiative flux difference of more than 10 W m−2 over 46 m of height was observed under weak-wind and clear-sky conditions after hot days. Wind speed variation can change not only the sensible heat transfer but also the surface longwave radiation because of variations of the area exposure of the warmer grass stems and soil surfaces versus the cooler grass blade tips, leading to fluctuations of the radiative flux divergence throughout the night.

Additional affiliation: Program in Atmospheric and Oceanic Sciences, University of Colorado, Boulder, Colorado

Corresponding author address: Jielun Sun, National Center for Atmospheric Research, 3450 Mitchell Lane, P.O. Box 3000, Boulder, CO 80307-3000. jsun@ucar.edu

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Journal of Applied Meteorology and Climatology

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