A Test of Ecological Optimality for Semiarid Vegetation

Prepared under the support of the National Aeronautics and Space Administration grant no. NAGW 1696 Three ecological optimality hypotheses (Eagleson, 1978 and 1982) which have utility in parameter reduction and estimation in a climate-soil-vegetation water balance model are reviewed and tested. The...

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Main Authors: Salvucci, Guido D., Eagleson, Peter S.
Language:unknown
Published: Cambridge, Mass. : Ralph M. Parsons Laboratory, Hydrology and Water Resource Systems, Massachusetts Institute of Technology, Dept. of Civil Engineering 1992
Subjects:
Beaver Creek
Online Access:https://hdl.handle.net/1721.1/143080
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record_format openpolar
spelling ftmit:oai:dspace.mit.edu:1721.1/143080 2023-06-11T04:10:37+02:00 A Test of Ecological Optimality for Semiarid Vegetation Salvucci, Guido D. Eagleson, Peter S. 1992-05 application/pdf https://hdl.handle.net/1721.1/143080 unknown Cambridge, Mass. : Ralph M. Parsons Laboratory, Hydrology and Water Resource Systems, Massachusetts Institute of Technology, Dept. of Civil Engineering R (Massachusetts Institute of Technology. Department of Civil Engineering) 92-17. Report (Ralph M. Parsons Laboratory for Water Resources and Hydrodynamics) 335. 335 https://hdl.handle.net/1721.1/143080 26912193 628633 1992 ftmit 2023-05-29T08:15:20Z Prepared under the support of the National Aeronautics and Space Administration grant no. NAGW 1696 Three ecological optimality hypotheses (Eagleson, 1978 and 1982) which have utility in parameter reduction and estimation in a climate-soil-vegetation water balance model are reviewed and tested. The first hypothesis involves short term optimization of vegetative canopy density through equilibrium soil moisture maximization. The second hypothesis involves vegetation type selection again through soil moisture maximization, and the third involves soil genesis through plant induced modification of soil hydraulic properties to values which result in a maximum rate of biomass productivity. The first hypothesis is found to be in excellent agreement with data observed at the Beaver Creek watershed in Central Arizona. The utility of this hypothesis in estimating soil properties is supported. The second hypothesis is found to be physically unrealistic and alternatives to the hypothesis are studied. Conditions at Beaver Creek are not appropriate for testing the third hypothesis. While the locus of canopy densities predicted by the short term ecological hypothesis creates a condition of stress free transpiration in typical years, lower than mean annual rainfall may still lead to drought-induced stress. In order to quantify this phenomenon, the expected value of the time spent in stress, and the resulting reduced transpiration, are analytically derived. The results of this analysis are shown to be useful in gaining a quantitative understanding of the water environment of semiarid regions and the drought tolerance required of its local vegetation. Other/Unknown Material Beaver Creek DSpace@MIT (Massachusetts Institute of Technology)
institution Open Polar
collection DSpace@MIT (Massachusetts Institute of Technology)
op_collection_id ftmit
language unknown
description Prepared under the support of the National Aeronautics and Space Administration grant no. NAGW 1696 Three ecological optimality hypotheses (Eagleson, 1978 and 1982) which have utility in parameter reduction and estimation in a climate-soil-vegetation water balance model are reviewed and tested. The first hypothesis involves short term optimization of vegetative canopy density through equilibrium soil moisture maximization. The second hypothesis involves vegetation type selection again through soil moisture maximization, and the third involves soil genesis through plant induced modification of soil hydraulic properties to values which result in a maximum rate of biomass productivity. The first hypothesis is found to be in excellent agreement with data observed at the Beaver Creek watershed in Central Arizona. The utility of this hypothesis in estimating soil properties is supported. The second hypothesis is found to be physically unrealistic and alternatives to the hypothesis are studied. Conditions at Beaver Creek are not appropriate for testing the third hypothesis. While the locus of canopy densities predicted by the short term ecological hypothesis creates a condition of stress free transpiration in typical years, lower than mean annual rainfall may still lead to drought-induced stress. In order to quantify this phenomenon, the expected value of the time spent in stress, and the resulting reduced transpiration, are analytically derived. The results of this analysis are shown to be useful in gaining a quantitative understanding of the water environment of semiarid regions and the drought tolerance required of its local vegetation.
author Salvucci, Guido D.
Eagleson, Peter S.
spellingShingle Salvucci, Guido D.
Eagleson, Peter S.
A Test of Ecological Optimality for Semiarid Vegetation
author_facet Salvucci, Guido D.
Eagleson, Peter S.
author_sort Salvucci, Guido D.
title A Test of Ecological Optimality for Semiarid Vegetation
title_short A Test of Ecological Optimality for Semiarid Vegetation
title_full A Test of Ecological Optimality for Semiarid Vegetation
title_fullStr A Test of Ecological Optimality for Semiarid Vegetation
title_full_unstemmed A Test of Ecological Optimality for Semiarid Vegetation
title_sort test of ecological optimality for semiarid vegetation
publisher Cambridge, Mass. : Ralph M. Parsons Laboratory, Hydrology and Water Resource Systems, Massachusetts Institute of Technology, Dept. of Civil Engineering
publishDate 1992
url https://hdl.handle.net/1721.1/143080
genre Beaver Creek
genre_facet Beaver Creek
op_relation R (Massachusetts Institute of Technology. Department of Civil Engineering)
92-17.
Report (Ralph M. Parsons Laboratory for Water Resources and Hydrodynamics)
335.
335
https://hdl.handle.net/1721.1/143080
26912193
628633
_version_ 1768385129307176960

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