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NOTE: Keihm 1984 + Birkebak 1974 | NOTE: Keihm 1984 + Birkebak 1974 | ||
| − | An analysis of the impact of ε(T) is performed using a typical TES basalt and a typical TES dust. | + | An analysis of the impact of ε(T) is performed using a typical TES basalt ([[File: bandfield_epf_derived_basalt_spectrum]]) and a typical TES dust ([[File:bandfield_epf_derived_dust_spectrum.txt]]). |
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| + | [[Image:TES_basalt.pdf|left|500px]] [[Image:TES_dust.pdf|center|500px]] | ||
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Equivalent broadband emissivities as a function of temperature are shown below. For a wide range of surface temperatures (50-500K), the broadband apparent emissivity only changes by small factors (1-2% at most). | Equivalent broadband emissivities as a function of temperature are shown below. For a wide range of surface temperatures (50-500K), the broadband apparent emissivity only changes by small factors (1-2% at most). | ||
Revision as of 14:34, 11 January 2019
k(T) all layers
k(T) = A+B*T+C*T^2+D*T^3
NOTE: Not just 2 domains/layers, but All
Cp(T) all layers
Cp(T) = A+B*T+C*T^2+D*T^3
NOTE: Not just 2 domains/layers, but All
Surface/Atmosphere Sensible heat exchange Q
Q = h × (Tsurf - Tatm)
NOTE: Tsurf is the kinetic surface Temperature; Tatm is the air temperature near the surface; Q is an additional heat flux term at the surface; h is a convective heat transfert coefficient.
Temperature-dependent Emissivity ε(T)
ε(T) = A + BxT + CxT^2 + DxT^3
NOTE: Keihm 1984 + Birkebak 1974
An analysis of the impact of ε(T) is performed using a typical TES basalt (File:bandfield epf derived basalt spectrum) and a typical TES dust (File:bandfield epf derived dust spectrum.txt).
File:TES basalt.pdf File:TES dust.pdf
Equivalent broadband emissivities as a function of temperature are shown below. For a wide range of surface temperatures (50-500K), the broadband apparent emissivity only changes by small factors (1-2% at most).
Excellent fits to these behaviors can be obtained with polynomial functions.
