Causes and implications of persistent atmospheric carbon dioxide biases in Earth System Models

F. M. Hoffman, J. T. Randerson, V. K. Arora, Q. Bao, P. Cadule, D. Ji, C. D. Jones, M. Kawamiya, S. Khatiwala, K. Lindsay, A. Obata, E. Shevliakova, K. D. Six, J. F. Tjiputra, E. M. Volodin, T. Wu

Research output: Contribution to journalArticlepeer-review

105 Scopus citations

Abstract

The strength of feedbacks between a changing climate and future CO 2 concentrations is uncertain and difficult to predict using Earth System Models (ESMs). We analyzed emission-driven simulations - in which atmospheric CO2levels were computed prognostically - for historical (1850-2005) and future periods (Representative Concentration Pathway (RCP) 8.5 for 2006-2100) produced by 15 ESMs for the Fifth Phase of the Coupled Model Intercomparison Project (CMIP5). Comparison of ESM prognostic atmospheric CO2 over the historical period with observations indicated that ESMs, on average, had a small positive bias in predictions of contemporary atmospheric CO2. Weak ocean carbon uptake in many ESMs contributed to this bias, based on comparisons with observations of ocean and atmospheric anthropogenic carbon inventories. We found a significant linear relationship between contemporary atmospheric CO2 biases and future CO 2levels for the multimodel ensemble. We used this relationship to create a contemporary CO2 tuned model (CCTM) estimate of the atmospheric CO2 trajectory for the 21st century. The CCTM yielded CO2estimates of 600±14 ppm at 2060 and 947±35 ppm at 2100, which were 21 ppm and 32 ppm below the multimodel mean during these two time periods. Using this emergent constraint approach, the likely ranges of future atmospheric CO2, CO2-induced radiative forcing, and CO2-induced temperature increases for the RCP 8.5 scenario were considerably narrowed compared to estimates from the full ESM ensemble. Our analysis provided evidence that much of the model-to-model variation in projected CO2 during the 21st century was tied to biases that existed during the observational era and that model differences in the representation of concentration-carbon feedbacks and other slowly changing carbon cycle processes appear to be the primary driver of this variability. By improving models to more closely match the long-term time series of CO2from Mauna Loa, our analysis suggests that uncertainties in future climate projections can be reduced. Key Points We analyzed emission-driven simulations from 15 Earth System Models (ESMs) Most ESMs had a small positive bias in contemporary atmospheric CO2 predictions We used a linear relationship to create a trajectory of future atmospheric CO2

Original languageEnglish
Pages (from-to)141-162
Number of pages22
JournalJournal of Geophysical Research: Biogeosciences
Volume119
Issue number2
DOIs
StatePublished - Feb 2014

Funding

FundersFunder number
National Science FoundationAGS-1048890
National Science Foundation1060804, 1048890

    Keywords

    • Intergovernmental Panel on Climate Change (IPCC)
    • climate warming
    • climate-carbon cycle feedbacks
    • greenhouse gases
    • terrestrial and oceanic carbon sinks
    • uncertainty quantification

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