Comparison of radiative and physiological effects of doubled atmospheric CO2 on climate

Comparison of radiative and physiological effects of doubled atmospheric CO2 on climate

The physiological response of terrestrial vegetation when directly exposed to an increase in atmospheric carbon dioxide (CO2) concentration could result in warming over the continents in addition to that due to the conventional CO2 "greenhouse effect." Results from a coupled biosphere-atmo...

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Veröffentlicht in:Science (American Association for the Advancement of Science) 1996-03, Vol.271 (5254), p.1402-1406
Hauptverfasser: SELLERS, P. J, BOUNOUA, L, JENSEN, T. G, COLLATZ, G. J, RANDALL, D. A, DAZLICH, D. A, LOS, S. O, BERRY, J. A, FUNG, I, TUCKER, C. J, FIELD, C. B
Format: Artikel
Sprache:eng
Schlagworte:
air temperature
atmosfera
Atmosphere
Atmospheric carbon dioxide
cambio climatico
canopy
carbon
Carbon dioxide
carbone
carbono
Climate
climatic change
couvert
cubierta de copas
dioxido de carbono
dioxyde de carbone
Earth sciences
Earth, ocean, space
Economic aspects
Energy
evapotranspiracion
evapotranspiration
Exact sciences and technology
fotosintesis
Global warming
Greenhouse effect
Marine and continental quaternary
modele de simulation
modelos de simulacion
Nutrition
photosynthese
photosynthesis
Physiology
precipitacion atmosferica
precipitation
simulation models
Surficial geology
temperatura del aire
temperature de l' air
transpiracion
transpiration
variation du climat
vegetacion
vegetation
Water
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Zusammenfassung:The physiological response of terrestrial vegetation when directly exposed to an increase in atmospheric carbon dioxide (CO2) concentration could result in warming over the continents in addition to that due to the conventional CO2 "greenhouse effect." Results from a coupled biosphere-atmosphere model (SiB2-GCM) indicate that, for doubled CO2 conditions, evapotranspiration will drop and air temperature will increase over the tropical continents, amplifying the changes resulting from atmospheric radiative effects. The range of responses in surface air temperature and terrestrial carbon uptake due to increased CO2 are projected to be inversely related in the tropics year-round and inversely related during the growing season elsewhere.
ISSN:0036-8075
1095-9203
DOI:10.1126/science.271.5254.1402