Accounting for Turbulence-Induced Canopy Heat Transfer in the Simulation of Sensible Heat Flux in SEBS Model

Surface turbulent heat fluxes are crucial for monitoring drought, heat waves, urban heat islands, agricultural water management, and other hydrological applications. Energy Balance Models (EBMs) are widely used to simulate surface heat fluxes from a combination of remote sensing-derived variables an...

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Bibliographic Details
Published in:Remote sensing (Basel, Switzerland) Switzerland), 2023-03, Vol.15 (6), p.1578
Main Authors: Njuki, Sammy M., Mannaerts, Chris M., Su, Zhongbo
Format: Article
Language:English
Subjects:
Accuracy
Agricultural management
Canopies
Datasets
Drought
EBMs
Energy
Energy balance
Enthalpy
Environmental aspects
Fluctuations
Foliage
foliage heat transfer coefficient
Forests
Heat flux
Heat transfer
Heat transfer coefficients
Heat waves
Height
Hydrology
kB−1
Mapping
Measurement
Meteorological data
Parameterization
Plant canopies
Radiation
Remote sensing
SEBS
Sensible heat
Simulation
Surface energy
Surface properties
surface turbulent heat fluxes
Testing
Time series
Turbulence
Urban agriculture
Urban heat islands
Variables
Vegetation
Water management
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Summary:Surface turbulent heat fluxes are crucial for monitoring drought, heat waves, urban heat islands, agricultural water management, and other hydrological applications. Energy Balance Models (EBMs) are widely used to simulate surface heat fluxes from a combination of remote sensing-derived variables and meteorological data. Single-source EBMs, in particular, are preferred in mapping surface turbulent heat fluxes due to their relative simplicity. However, most single-source EBMs suffer from uncertainties inherent to the parameter kB−1, which is used to account for differences in the source of heat and the sink of momentum when representing aerodynamic resistance in single-source EBMs. For instance, the parameterization of kB−1 in the commonly used single-source Surface Energy Balance System (SEBS) model uses a constant value of the foliage heat transfer coefficient (Ct), in the parameterization of the vegetation component of kB−1 (kBv−1). Thus, SEBS ignores the effect of turbulence on canopy heat transfer. As a result, SEBS has been found to greatly underestimate sensible heat flux in tall forest canopies, where turbulence is a key contributor to canopy heat transfer. This study presents a revised parameterization of kBv−1 for the SEBS model. A physically based formulation of Ct, which considers the effect of turbulence on Ct, is used in deriving the revised parameterization. Simulation results across 15 eddy covariance (EC) flux tower sites show that the revised parameterization significantly reduces the underestimation of sensible heat flux compared to the original parameterization under tall forest canopies. The revised parameterization is relatively simple and does not require additional information on canopy structure compared to some more complex parameterizations proposed in the literature. As such, the revised parameterization is suitable for mapping surface turbulent heat fluxes, especially under tall forest canopies.
ISSN:2072-4292
2072-4292
DOI:10.3390/rs15061578