A land-surface process/radiobrightness model with coupled heat and moisture transport for freezing soils

• Published in: IEEE transactions on geoscience and remote sensing Vol. 36; no. 2; pp. 669 - 677
• Main Authors: Yuei-An Liou, England, A.W.
• Format: Journal Article
• Language: English
• Published: New York, NY IEEE 01.03.1998; Institute of Electrical and Electronics Engineers
• Subjects: Atmosphere; Atmospheric measurements; Atmospheric modeling; Earth sciences; Earth, ocean, space; Exact sciences and technology; Heating; Hydrologic measurements; Hydrology; Moisture measurement; Soil measurements; Soils; Surficial geology; Temperature sensors; Water resources; United States; Great Plains; atmosphere; thawing; models; soil moisture; hydrology; liquid phase; remote sensing; digital simulation; microwave methods; transport; North America; water; insolation; brightness; freezing; one-dimensional models; plains; soil profiles; cooling; temperature; soils; energy
• ISSN: 0196-2892
• DOI: 10.1109/36.662747

Phase change of water is an important sink and source of energy and moisture within soils as well as a significant influence upon soil temperature and moisture profiles. These profiles play a crucial role in governing energy and moisture fluxes between bare soils and the atmosphere. They also codetermine radiobrightness, so that the difference between modeled and observed radiobrightness becomes a measure of error in a model's estimate of temperature or moisture. The authors present a physically based, coupled-heat and moisture-transport, one-dimensional hydrology/radiobrightness (1 dH/R) model for bare, freezing and thawing, moist soils that are subject to insolation, radiant heating and cooling, and sensible and latent heat exchanges with the atmosphere. They use this model to examine thermal, hydrologic, and Special Sensor Microwave/Imager (SSMI) radiobrightness signatures for a three-month, dry-down simulation in the fall and winter of the northern United States Great Plains as part of an investigation of the effects of coupling heat and moisture transport. Given a typical initial moisture content of 38%, they find that coupled transport results in a reduction of ice in the surface soil by 21%. The range of diurnal variations in temperature are not significantly affected by coupled transport. Diurnal variations in the 19-GHz, H-polarized radiobrightness can be greater in the coupled transport case by 37 K. Total diurnal variation can exceed 57 K during periods of diurnal freezing and thawing.