On the Effective Surface Temperature of a Natural Landscape: Infrared or Not Infrared

Statistical methods are employed to assess the extent to which measurements of temperature using downward looking infrared thermometry ( T 0 ) are indicative of the effective boundary between the air and the subsurface environment. An effective interfacial surface temperature ( T e ) is determined f...

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Bibliographic Details
Published in:Boundary-layer meteorology 2021-08, Vol.180 (2), p.353-362
Main Authors: Hicks, Bruce B., Eash, Neal S.
Format: Article
Language:English
Subjects:
Air
Air temperature
Atmospheric Protection/Air Quality Control/Air Pollution
Atmospheric Sciences
Cereal crops
Corn
Data collection
Datasets
Earth and Environmental Science
Earth Sciences
Enthalpy
Field study
Heat flux
Heat transfer
Infrared thermometry
Meteorology
Multimedia
Notes and Comments
Rain
Roughness
Roughness length
Satellites
Sensible heat
Sensible heat flux
Sensible heat transfer
Soil temperature
Statistical methods
Surface temperature
Temperature
Temperature data
Temperature measurement
Temperature measurements
Thermometry
Vegetation
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Summary:Statistical methods are employed to assess the extent to which measurements of temperature using downward looking infrared thermometry ( T 0 ) are indicative of the effective boundary between the air and the subsurface environment. An effective interfacial surface temperature ( T e ) is determined from consideration of in-air ( T a ) and subsurface ( T s ) temperature data, being that which best satisfies the multi-media (air and soil) flux relationships. Using data obtained in studies conducted in Ohio in 2015, it is shown that during the daytime measured values of T 0 exceeded T e by an amount reaching a near-noon maximum of about 2 °C when the crop (maize) was fully grown. Night-time observations indicated a near equality of T 0 and T e , although often equality appears threatened by the presence of strongly stable layers in air near the surface. Ramifications of the observed differences are discussed, with particular attention to implications regarding determination of the thermal roughness length associated with the sensible heat flux.
ISSN:0006-8314
1573-1472
DOI:10.1007/s10546-021-00626-0