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Thermophysics in general is the geological application of thermal physics which is related to the classical physics study of thermal science. == Remote Sensing == Earth thermophysics is a branch of geophysics that uses the naturally occurring surface temperature as a function of the cyclical variation in solar radiation to charactertize planetary material properties. Thermophysical properties are characteristics that control the diurnal, seasonal, or climatic surface and subsurface temperature variations (or thermal curves) of a material. The most important thermophysical property is thermal inertia, which controls the amplitude of the thermal curve and albedo (or reflectivity), which controls the average temperature. This field of observations and computer modeling was first applied to Mars due to the ideal atmospheric pressure for characterizing granular materials based upon temperature (and Glaser, 1965 ). The Mariner 6, Mariner 7, and Mariner 9 spacecraft carried thermal infrared radiometers (et al., 1971; Kieffer et al., 1973 ), and a global map of thermal inertia was produced from modeled surface temperatures (et al., 1977 ) collected by the Infrared Thermal Mapper Instruments (IRTM) on board the Viking 1 and 2 Orbiters. The original thermophysical models were based upon the studies of lunar temperature variations by Wesselink () and Jaeger (). Further development of the models for Mars included surface-atmosphere energy transfer (1966 ), atmospheric back-radiation (et al., 1971 ), surface emissivity variations (et al., 1973 ), CO2 frost and blocky surfaces (et al., 1977 ), variability of atmospheric back-radiation (and Jakosky, 1991 ), effects of a radiative-convective atmosphere (et al., 1995 ), and single-point temperature observations (et al., 2000; Mellon et al., 2000 ). 抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)』 ■ウィキペディアで「Thermophysics」の詳細全文を読む スポンサード リンク
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