Influence of carbon-nitrogen cycle coupling on land model response to CO2 fertilization and climate variability

Nutrient cycling affects carbon uptake by the terrestrial biosphere and imposes controls on carbon cycle response to variation in temperature and precipitation, but nutrient cycling is ignored in most global coupled models of the carbon cycle and climate system. We demonstrate here that the inclusio...

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Bibliographic Details
Published in:Global biogeochemical cycles 2007-12, Vol.21 (4), p.n/a
Main Authors: Thornton, P.E, Lamarque, J.F, Rosenbloom, N.A, Mahowald, N.M
Format: Article
Language:English
Subjects:
air temperature
Animal and plant ecology
Animal, plant and microbial ecology
biogeochemical cycles
Biological and medical sciences
carbon
carbon cycle
carbon dioxide
climate models
Community Climate System Model
coupled model
Earth sciences
Earth, ocean, space
elevated atmospheric gases
Exact sciences and technology
Fundamental and applied biological sciences. Psychology
General aspects
Geochemistry
nitrogen
nitrogen cycle
precipitation
simulation models
Synecology
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Summary:Nutrient cycling affects carbon uptake by the terrestrial biosphere and imposes controls on carbon cycle response to variation in temperature and precipitation, but nutrient cycling is ignored in most global coupled models of the carbon cycle and climate system. We demonstrate here that the inclusion of nutrient cycle dynamics, specifically the close coupling between carbon and nitrogen cycles, in a terrestrial biogeochemistry component of a global coupled climate system model leads to fundamentally altered behavior for several of the most critical feedback mechanisms operating between the land biosphere and the global climate system. Carbon‐nitrogen cycle coupling reduces the simulated global terrestrial carbon uptake response to increasing atmospheric CO2 concentration by 74%, relative to a carbon‐only counterpart model. Global integrated responses of net land carbon exchange to variation in temperature and precipitation are significantly damped by carbon‐nitrogen cycle coupling. The carbon cycle responses to temperature and precipitation variation are reduced in magnitude as atmospheric CO2 concentration rises for the coupled carbon‐nitrogen model, but increase in magnitude for the carbon‐only counterpart. Our results suggest that previous carbon‐only treatments of climate‐carbon cycle coupling likely overestimate the terrestrial biosphere's capacity to ameliorate atmospheric CO2 increases through direct fertilization. The next generation of coupled climate‐biogeochemistry model projections for future atmospheric CO2 concentration and climate change should include explicit, prognostic treatment of terrestrial carbon‐nitrogen cycle coupling.
ISSN:0886-6236
1944-9224
DOI:10.1029/2006GB002868