Freezing and Thawing of Soils Under the Influence of 300- and 90-Year Periods of Temperature Fluctuation

Mathematical modeling of perennial freeze and thaw is used in geocryology to solve both scientific and engineering problems. The surface temperature of a substrate is given as either a constant (stationary problem) or a function with a fixed period of fluctuation (periodic problem). In this paper a...

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Bibliographic Details
Main Authors: Romanovsky, V.E., Garagula, L.S., Seregina, N.V.
Other Authors: MOSCOW STATE UNIV (USSR) DEPT OF GEOLOGY
Format: Text
Language:English
Published: 1992
Subjects:
Geography
Snow
Ice and Permafrost
Meteorology
Geology
Geochemistry and Mineralogy
*CLIMATE
*HEAT TRANSMISSION
*MATHEMATICAL MODELS
*PERMAFROST
*SOILS
*TEMPERATURE
*THAWING
BOREHOLES
BOUNDARIES
DYNAMICS
ENGINEERING
ENTHALPY
FLOW
FUNCTIONS
GRIDS
HEAT
LATENT HEAT
MODELS
ONE DIMENSIONAL
PROFILES
REGIONS
SIBERIA
SITES
STRUCTURES
SUBSTRATES
SURFACE TEMPERATURE
SURFACES
TWO DIMENSIONAL
ARCTIC REGIONS
SYMPOSIA
Component Reports
*Freeze
*Geocryology
*Fluctuations
Arctic
Climate change
Ice
permafrost
Siberia
Online Access:http://www.dtic.mil/docs/citations/ADP007337
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADP007337
Description
Summary:Mathematical modeling of perennial freeze and thaw is used in geocryology to solve both scientific and engineering problems. The surface temperature of a substrate is given as either a constant (stationary problem) or a function with a fixed period of fluctuation (periodic problem). In this paper a numerical permafrost model is developed for the southern Siberia region to study the influence of rhythmic climate change on the dynamics of permafrost. The mathematical model is represented as a two-dimensional heat conduction problem for a moist substrate with the latent heat effect for complex geological structures. This model takes into account a complex periodic temperature change at the soil surface and a stable heat flow at the lower and lateral boundaries for a steady domain. The enthalpy method to arrive at a numerical solution for this problem is used. It has been realized as a fully implicit local one-dimensional finite-difference scheme on an irregular grid. The calculations of the dynamics of temperature fields and permafrost boundaries are discussed to evaluate this scheme for the southern permafrost region of Eastern Siberia. The modeled results show that transects of temperature fields along some profiles (particularly at sites with complex geological structures) contain more information about permafrost dynamics than do ground temperature profiles from isolated boreholes.

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