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Quantifying uncertainty in the biospheric carbon flux for England and Wales

Kennedy, M.C., Anderson, C.W., Lomas, M., Woodward, F.I., Heinemeyer, A. (orcid.org/0000-0003-3151-2466), Gosling, J.P. and O'Hagan, A. (2008) Quantifying uncertainty in the biospheric carbon flux for England and Wales. Journal of the Royal Statistical Society: Series A (Statistics in Society). pp. 109-135. ISSN 1467-985X

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A crucial issue in the current global warming debate is the effect of vegetation and soils on carbon dioxide (CO2) concentrations in the atmosphere. Vegetation can extract CO2 through photosynthesis, but respiration, decay of soil organic matter and disturbance effects such as fire return it to the atmosphere. The balance of these processes is the net carbon flux. To estimate the biospheric carbon flux for England and Wales, we address the statistical problem of inference for the sum of multiple outputs from a complex deterministic computer code whose input parameters are uncertain. The code is a process model which simulates the carbon dynamics of vegetation and soils, including the amount of carbon that is stored as a result of photosynthesis and the amount that is returned to the atmosphere through respiration. The aggregation of outputs corresponding to multiple sites and types of vegetation in a region gives an estimate of the total carbon flux for that region over a period of time. Expert prior opinions are elicited for marginal uncertainty about the relevant input parameters and for correlations of inputs between sites. A Gaussian process model is used to build emulators of the multiple code outputs and Bayesian uncertainty analysis is then used to propagate uncertainty in the input parameters through to uncertainty on the aggregated output. Numerical results are presented for England and Wales in the year 2000. It is estimated that vegetation and soils in England and Wales constituted a net sink of 7.55 Mt C (1 Mt C = 10(12) g of carbon) in 2000, with standard deviation 0.56 Mt C resulting from the sources of uncertainty that are considered.

Item Type: Article
Copyright, Publisher and Additional Information: © 2008 Royal Statistical Society. This is an author produced version of a paper published in 'Journal of the Royal Statistical Society'. Uploaded in accordance with the self-archiving policy of the copyright holder.
Keywords: carbon flux,climate change,computer experiments,dynamic vegetation models,emulation,Gaussian process,net biome productivity,sensitivity analysis,uncertainty analysis,MODELS,CO2,Economics and Econometrics,Statistics and Probability,Social Sciences (miscellaneous)
Institution: The University of York
Academic Units: The University of York > Stockholm Environment Institute at York (York)
Depositing User: Mrs Megan Hobbs
Date Deposited: 16 Mar 2010 18:37
Last Modified: 10 Jul 2016 00:02
Published Version: http://dx.doi.org/10.1111/j.1467-985X.2007.00489.x
Status: Published
Refereed: Yes
Related URLs:
URI: http://eprints.whiterose.ac.uk/id/eprint/10599

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