Sensitivities of the Australian terrestrial water and carbon balances to climate change and variability

•Over Australia, temperature and CO2 trends will have opposite effects on evapotranspiration.•Runoff is much more sensitive to climate change than evapotranspiration.•Soil moisture is much less sensitive to climate change than evapotranspiration.•Net ecosystem production is increased by rising CO2 b...

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Published in:Agricultural and forest meteorology 2013-12, Vol.182-183, p.277-291
Main Authors: Raupach, M.R., Haverd, V., Briggs, P.R.
Format: Article
Language:English
Subjects:
Australia
biogeochemical cycles
Carbon
Carbon balance
Carbon cycle
Carbon dioxide
Climate change
Climate variability
evapotranspiration
net ecosystem production
rain
Reduction
Runoff
Sensitivity
soil water
Stores
temperate zones
Water balance
water use efficiency
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cited_by cdi_FETCH-LOGICAL-c454t-3f7f8d759c790eda55b5d310402875c9bb237289e8aab649f078ad5eb44399813
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container_title Agricultural and forest meteorology
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creator Raupach, M.R.
Haverd, V.
Briggs, P.R.
description •Over Australia, temperature and CO2 trends will have opposite effects on evapotranspiration.•Runoff is much more sensitive to climate change than evapotranspiration.•Soil moisture is much less sensitive to climate change than evapotranspiration.•Net ecosystem production is increased by rising CO2 but reduced by warming. To assess both past and future responses of the coupled terrestrial water and carbon cycles to climate change and variability, it is important to characterise the sensitivities of water and carbon fluxes and stores to long-term changes in drivers such as precipitation (P), temperature (T) and CO2 concentration. Here we quantify observed sensitivities using a well-calibrated terrestrial biosphere model and data for the Australian continent, and thereby infer likely changes to the water and carbon cycles under specified scenarios for future changes in the drivers. We find: (1) evapotranspiration (ET) has a large positive sensitivity to P, a positive sensitivity to T, and a negative sensitivity to CO2 through increased plant water use efficiency with rising CO2. Consequently, likely changes in T and CO2 over the next half century will have opposite and nearly cancelling effects on ET. (2) Runoff has a large sensitivity to P (positive) and significant sensitivities to T (negative) and CO2 (positive). These sensitivities are largest in cool temperate regions, where major contributors to likely long-term changes in runoff are decreased P (where a 5% rainfall reduction would lead to a 12% decrease in runoff), increased T (with a warming of 1.5K leading to an additional 6% decrease in runoff), and response to CO2 (with an increase of 100ppm causing an offsetting 6% increase in runoff). (3) Sensitivities of soil moisture to P, T and CO2 have similar signs and spatial patterns to those for runoff, but are smaller in magnitude by a factor of 5–10. (4) In the terrestrial carbon cycle, net ecosystem production (NEP) is increased by rising CO2 but simultaneously reduced (and nearly cancelled in likely scenarios) by warming.
doi_str_mv 10.1016/j.agrformet.2013.06.017
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To assess both past and future responses of the coupled terrestrial water and carbon cycles to climate change and variability, it is important to characterise the sensitivities of water and carbon fluxes and stores to long-term changes in drivers such as precipitation (P), temperature (T) and CO2 concentration. Here we quantify observed sensitivities using a well-calibrated terrestrial biosphere model and data for the Australian continent, and thereby infer likely changes to the water and carbon cycles under specified scenarios for future changes in the drivers. We find: (1) evapotranspiration (ET) has a large positive sensitivity to P, a positive sensitivity to T, and a negative sensitivity to CO2 through increased plant water use efficiency with rising CO2. Consequently, likely changes in T and CO2 over the next half century will have opposite and nearly cancelling effects on ET. 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ispartof Agricultural and forest meteorology, 2013-12, Vol.182-183, p.277-291
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1873-2240
language eng
recordid cdi_proquest_miscellaneous_1642237496
source Elsevier
subjects Australia
biogeochemical cycles
Carbon
Carbon balance
Carbon cycle
Carbon dioxide
Climate change
Climate variability
evapotranspiration
net ecosystem production
rain
Reduction
Runoff
Sensitivity
soil water
Stores
temperate zones
Water balance
water use efficiency
title Sensitivities of the Australian terrestrial water and carbon balances to climate change and variability
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