Modeling plant-soil-atmosphere carbon dioxide exchange using optimality principles

The exchange of carbon dioxide (CO2) between terrestrial ecosystems and the atmosphere plays a central role in the ecology of the biosphere and the climate system. Towards quantification of ecosystem-atmosphere CO 2 exchange, a generalized model of plant-soil-atmosphere CO2 exchange (OPTICAL) was de...

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Main Author: Tu, Kevin Patrick
Format: Text
Language:unknown
Published: University of New Hampshire Scholars' Repository 2000
Subjects:
Biology
Ecology
Biogeochemistry
Arctic
Online Access:https://scholars.unh.edu/dissertation/2131
https://scholars.unh.edu/cgi/viewcontent.cgi?article=3130&context=dissertation
id ftuninhampshire:oai:scholars.unh.edu:dissertation-3130
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spelling ftuninhampshire:oai:scholars.unh.edu:dissertation-3130 2023-05-15T15:15:48+02:00 Modeling plant-soil-atmosphere carbon dioxide exchange using optimality principles Tu, Kevin Patrick 2000-01-01T08:00:00Z application/pdf https://scholars.unh.edu/dissertation/2131 https://scholars.unh.edu/cgi/viewcontent.cgi?article=3130&context=dissertation unknown University of New Hampshire Scholars' Repository https://scholars.unh.edu/dissertation/2131 https://scholars.unh.edu/cgi/viewcontent.cgi?article=3130&context=dissertation Doctoral Dissertations Biology Ecology Biogeochemistry text 2000 ftuninhampshire 2023-01-30T21:21:21Z The exchange of carbon dioxide (CO2) between terrestrial ecosystems and the atmosphere plays a central role in the ecology of the biosphere and the climate system. Towards quantification of ecosystem-atmosphere CO 2 exchange, a generalized model of plant-soil-atmosphere CO2 exchange (OPTICAL) was described and evaluated using eddy covariance measurements of net ecosystem exchange of CO2 (NEE) in arctic, boreal, temperate, and tropical landscapes. The model requires no calibration and is based on theories of plant resource optimization and plant-soil nutrient feedbacks. The model predicts canopy photosynthetic capacity (Pcmax), canopy photosynthesis (P c), plant respiration (Rp), and soil heterotrophic respiration (RH). It can be applied globally using satellite-derived estimates of canopy light absorptance (f APAR), incident radiation (PAR), and air temperature (T air). The model provides the means by which to relate satellite observations such as the Normalized Difference Vegetation Index (NDVI) to the physiological status of vegetation and to ecosystem-atmosphere carbon exchange. A unique aspect of the model is its use of a recursive filter for calculating photosynthetic acclimation based on the integrated effect of environmental conditions. Good agreement was found between modeled and observed Pcmax (r2 = 0.76), the latter derived from light response curves fit to estimates of gross ecosystem exchange (GEE). Consistent with theories of resource optimization, P cmax varied strongly with time-averaged absorbed PAR and temperature. Modeled Pcmax combined with a 'big-leaf' canopy model explained 74 to 85% of the variability in GEE. The photo-acclimation model not only performed better than a traditional time-invariant model and as good or better than calibrated site-specific models, it did not require knowledge of vegetation type. The process of photo-acclimation appeared most important during periods of greatest transition in plant physiological status (e.g. spring and fall). Agreement between modeled and ... Text Arctic University of New Hampshire: Scholars Repository Arctic
institution Open Polar
collection University of New Hampshire: Scholars Repository
op_collection_id ftuninhampshire
language unknown
topic Biology
Ecology
Biogeochemistry
spellingShingle Biology
Ecology
Biogeochemistry
Tu, Kevin Patrick
Modeling plant-soil-atmosphere carbon dioxide exchange using optimality principles
topic_facet Biology
Ecology
Biogeochemistry
description The exchange of carbon dioxide (CO2) between terrestrial ecosystems and the atmosphere plays a central role in the ecology of the biosphere and the climate system. Towards quantification of ecosystem-atmosphere CO 2 exchange, a generalized model of plant-soil-atmosphere CO2 exchange (OPTICAL) was described and evaluated using eddy covariance measurements of net ecosystem exchange of CO2 (NEE) in arctic, boreal, temperate, and tropical landscapes. The model requires no calibration and is based on theories of plant resource optimization and plant-soil nutrient feedbacks. The model predicts canopy photosynthetic capacity (Pcmax), canopy photosynthesis (P c), plant respiration (Rp), and soil heterotrophic respiration (RH). It can be applied globally using satellite-derived estimates of canopy light absorptance (f APAR), incident radiation (PAR), and air temperature (T air). The model provides the means by which to relate satellite observations such as the Normalized Difference Vegetation Index (NDVI) to the physiological status of vegetation and to ecosystem-atmosphere carbon exchange. A unique aspect of the model is its use of a recursive filter for calculating photosynthetic acclimation based on the integrated effect of environmental conditions. Good agreement was found between modeled and observed Pcmax (r2 = 0.76), the latter derived from light response curves fit to estimates of gross ecosystem exchange (GEE). Consistent with theories of resource optimization, P cmax varied strongly with time-averaged absorbed PAR and temperature. Modeled Pcmax combined with a 'big-leaf' canopy model explained 74 to 85% of the variability in GEE. The photo-acclimation model not only performed better than a traditional time-invariant model and as good or better than calibrated site-specific models, it did not require knowledge of vegetation type. The process of photo-acclimation appeared most important during periods of greatest transition in plant physiological status (e.g. spring and fall). Agreement between modeled and ...
format Text
author Tu, Kevin Patrick
author_facet Tu, Kevin Patrick
author_sort Tu, Kevin Patrick
title Modeling plant-soil-atmosphere carbon dioxide exchange using optimality principles
title_short Modeling plant-soil-atmosphere carbon dioxide exchange using optimality principles
title_full Modeling plant-soil-atmosphere carbon dioxide exchange using optimality principles
title_fullStr Modeling plant-soil-atmosphere carbon dioxide exchange using optimality principles
title_full_unstemmed Modeling plant-soil-atmosphere carbon dioxide exchange using optimality principles
title_sort modeling plant-soil-atmosphere carbon dioxide exchange using optimality principles
publisher University of New Hampshire Scholars' Repository
publishDate 2000
url https://scholars.unh.edu/dissertation/2131
https://scholars.unh.edu/cgi/viewcontent.cgi?article=3130&context=dissertation
geographic Arctic
geographic_facet Arctic
genre Arctic
genre_facet Arctic
op_source Doctoral Dissertations
op_relation https://scholars.unh.edu/dissertation/2131
https://scholars.unh.edu/cgi/viewcontent.cgi?article=3130&context=dissertation
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