On the atmospheric dependence of the split-window equation for land surface temperature

Abstract

A split-window equation is derived for land surface temperature, yielding T = T₄ + A(T₄ − T₅) + B(ε), where T is the true surface temperature, T₄ and T₅ are the brightness temperatures measured in AVHRR channels 4 and 5, A is a coefficient related to the atmospheric transmittances in AVHRR channels 4 and 5, being dependent on the atmosphere type and independent on surface emissivity, and B(ε) takes into account the emissivity effect, which depends on both the channel surface emissivities (ε₄ and ε₅) and the atmosphere type. The atmospheric dependence of split-window coefficients, A and B(ε), is discussed by means of satellite measurements simulations and in situ data. It is shown that linear, global-scale algorithms can produce inaccurate estimates of surface temperature when they are applied to areas of reduced atmospheric variability. A simple, non-linear split-window algorithm has been proposed, in which A = a₀+ a₁(T₄− T₅). The constants a₀and a₁ have been calculated from a set of in situ and coincident satellite measurements of sea surface temperatures taken over a wide range of latitudes. A linear split-window algorithm optimized for mid-latitude conditions has been also derived. The combined effects of atmospheric attenuation and surface emissivity on T₄ − T₅ have been discussed. Moreover, the theoretical results derived are applied to a NOAA-9 image, for which a procedure for estimating the channel emissivity difference (ε₄ − ε₅) using satellite sensor data is suggested.