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Future directions for hydropedology: quantifying impacts of global change on land use (2009)

Vepraskas, M. J. ; Heitman, J. L. ; Austin, R. E.

Copernicus

In: Hydrology and Earth System Sciences. 2009; 13(8): 1427-1438. Published 2009 Aug 12. doi: 10.5194/hess-13-1427-2009.

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Publication Date: 2009-08-12

Description: Hydropedology is well positioned to address contemporary issues resulting from climate change. We propose a six-step process by which digital, field-scale maps will be produced to show where climate change impacts will be greatest for two land uses: a) home sites using septic systems, and b) wetlands. State and federal laws have defined critical water table levels that can be used to determine where septic systems will function well or fail, and where wetlands are likely to occur. Hydrologic models along with historic rainfall and temperature data can be used to compute long records of water table data. However, it is difficult to extrapolate such data across land regions, because too little work has been done to test different ways for doing this reliably. The modeled water table data can be used to define soil drainage classes for individual mapping units, and the drainage classes used to extrapolate the data regionally using existing digital soil survey maps. Estimates of changes in precipitation and temperature can also be input into the models to compute changes to water table levels and drainage classes. To do this effectively, more work needs to be done on developing daily climate files from the monthly climate change predictions. Technology currently exists to use the NRCS Soil Survey Geographic (SSURGO) Database with hydrologic model predictions to develop maps within a GIS that show climate change impacts on septic system performance and wetland boundaries. By using these maps, planners will have the option to scale back development in sensitive areas, or simply monitor the water quality of these areas for pathogenic organisms. The calibrated models and prediction maps should be useful throughout the Coastal Plain region. Similar work for other climate-change and land-use issues can be a valuable contribution from hydropedologists.

Print ISSN: 1027-5606

Electronic ISSN: 1607-7938

Topics: Geography , Geosciences

Published by Copernicus on behalf of European Geosciences Union.

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Future directions for hydropedology: quantifying impacts of global change on land use (2009)

Vepraskas, M. J. ; Heitman, J. L. ; Austin, R. E.

Copernicus

In: Hydrology and Earth System Sciences Discussions. 2009; 6(2): 1737-1768. Published 2009 Mar 05. doi: 10.5194/hessd-6-1737-2009.

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Publication Date: 2009-03-05

Description: Hydropedology is well positioned to address contemporary issues resulting from climate change. We propose a six step process by which digital, field-scale maps will be produced to show where climate change impacts will be greatest for two land uses: a) home sites using septic systems, and b) wetlands. State and federal laws have defined critical water table levels that can be used to determine where septic systems will function well or fail, and where wetlands are likely to occur. Hydrologic models along with historic rainfall and temperature data can be used to compute long records of water table data. However, it is difficult to extrapolate such data across land regions, because too little work has been done to test different ways for doing this reliably. The modeled water table data can be used to define soil drainage classes for individual mapping units, and the drainage classes used to extrapolate the data regionally using existing digital soil survey maps. Estimates of changes in precipitation and temperature can also be input into the models to compute changes to water table levels and drainage classes. To do this effectively, more work needs to be done on developing daily climate files from the monthly climate change predictions. Technology currently exists to use the NRCS Soil Survey Geographic (SSURGO) Database with hydrologic model predictions to develop maps within a GIS that show climate change impacts on septic system performance and wetland boundaries. By using these maps, planners will have the option to scale back development in sensitive areas, or simply monitor the water quality of these areas for pathogenic organisms. The calibrated models and prediction maps should be useful throughout the Coastal Plain region. Similar work for other climate-change and land-use issues can be a valuable contribution from hydropedologists.

Print ISSN: 1812-2108

Electronic ISSN: 1812-2116

Topics: Geography , Geosciences

Published by Copernicus on behalf of European Geosciences Union.

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Sensible Heat Observations Reveal Soil-Water Evaporation Dynamics (2008)

Heitman, J. L. ; Horton, R. ; Sauer, T. J. ; [et al.]

American Meteorological Society

In: Journal of Hydrometeorology. 2008; 9(1): 165-171. Published 2008 Feb 01. doi: 10.1175/2007jhm963.1.

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Publication Date: 2008-02-01

Description: Soil-water evaporation is important at scales ranging from microbial ecology to large-scale climate. Yet routine measurements are unable to capture rapidly shifting near-surface soil heat and water processes involved in soil-water evaporation. The objective of this study was to determine the depth and location of the evaporation zone within soil. Three-needle heat-pulse sensors were used to monitor soil heat capacity, thermal conductivity, and temperature below a bare soil surface in central Iowa during natural wetting/drying cycles. Soil heat flux and changes in heat storage were calculated from these data to obtain a balance of sensible heat components. The residual from this balance, attributed to latent heat from water vaporization, provides an estimate of in situ soil-water evaporation. As the soil dried following rainfall, results show divergence in the soil sensible heat flux with depth. Divergence in the heat flux indicates the location of a heat sink associated with soil-water evaporation. Evaporation estimates from the sensible heat balance provide depth and time patterns consistent with observed soil-water depletion patterns. Immediately after rainfall, evaporation occurred near the soil surface. Within 6 days after rainfall, the evaporation zone proceeded 〉 13 mm into the soil profile. Evaporation rates at the 3-mm depth reached peak values 〉 0.25 mm h−1. Evaporation occurred simultaneously at multiple measured depth increments, but with time lag between peak evaporation rates for depths deeper below the soil surface. Implementation of finescale measurement techniques for the soil sensible heat balance provides a new opportunity to improve understanding of soil-water evaporation.

Print ISSN: 1525-755X

Electronic ISSN: 1525-7541

Topics: Geography , Geosciences , Physics

Published by American Meteorological Society

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