Reliable, robust and realistic: the three R's of next-generation land-surface modelling

Prentice, Iain Colin; Liang, Xu; Medlyn, Belinda E.; Wang, Ying‐Ping

doi:10.5194/acp-15-5987-2015

Cited by 194 publications

(161 citation statements)

References 173 publications

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“…A significant part of those differences can be attributed to the differences in their model components, model parameter values [Friedlingstein et al, 2013;Prentice et al, 2015], and model input [Fekete et al, 2004]. For example, the one standard deviation of the simulated net carbon uptake from 1900 to 2100 by different global land models increased steadily from 117 to 259 Gt C, while the mean amount of C uptake as estimated by different models remained between 326 and 410 Gt C over the last three successive assessment reports by the IPCC.…”

Section: Introductionmentioning

confidence: 99%

“…Large discrepancies have been found among the simulated gross primary production (GPP) and latent heat (LE) fluxes by the most advanced earth system models in the most recent assessment report (AR) by the International Panel on Climate Change (IPCC) [Ciais et al, 2013], and those differences have not decreased over the last three successive assessments by the IPCC [Prentice et al, 2015]. A significant part of those differences can be attributed to the differences in their model components, model parameter values [Friedlingstein et al, 2013;Prentice et al, 2015], and model input [Fekete et al, 2004].…”

Section: Introductionmentioning

confidence: 99%

“…For example, the one standard deviation of the simulated net carbon uptake from 1900 to 2100 by different global land models increased steadily from 117 to 259 Gt C, while the mean amount of C uptake as estimated by different models remained between 326 and 410 Gt C over the last three successive assessment reports by the IPCC. Among the 12 earth system models for the fifth assessment report of IPCC, only the mean annual gross primary production (GPP) and latent heat flux (LE) by two models fall within the ranges based on observations [Prentice et al, 2015]. Therefore, quantification and attribution of those errors in land surface models are essential for future model improvement and development [Luo et al, 2012].…”

Section: Introductionmentioning

confidence: 99%

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Quantification and attribution of errors in the simulated annual gross primary production and latent heat fluxes by two global land surface models

Wang

Duan

et al. 2016

J Adv Model Earth Syst

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Differences in the predicted carbon and water fluxes by different global land models have been quite large and have not decreased over the last two decades. Quantification and attribution of the uncertainties of global land surface models are important for improving the performance of global land surface models, and are the foci of this study. Here we quantified the model errors by comparing the simulated monthly global gross primary productivity (GPP) and latent heat flux (LE) by two global land surface models with the model-data products of global GPP and LE from 1982 to 2005. By analyzing model parameter sensitivities within their ranges, we identified about 2-11 most sensitive model parameters that have strong influences on the simulated GPP or LE by two global land models, and found that the sensitivities of the same parameters are different among the plant functional types (PFT). Using parameter ensemble simulations, we found that 15%-60% of the model errors were reduced by tuning only a few (<4) most sensitive parameters for most PFTs, and that the reduction in model errors varied spatially within a PFT or among different PFTs. Our study shows that future model improvement should optimize key model parameters, particularly those parameters relating to leaf area index, maximum carboxylation rate, and stomatal conductance.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Quantification and attribution of errors in the simulated annual gross primary production and latent heat fluxes by two global land surface models

Wang

Duan

et al. 2016

J Adv Model Earth Syst

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“…Within the context of the history of land surface modeling, the SEDGES framework (defined as SEDGES and the type of land surface model that it presupposes that it forms a part of) combines aspects of first-and thirdgeneration models (Sellers et al, 1997;Pitman, 2003;Prentice et al, 2015), which include, respectively, the use of a simple single-layer "bucket" model for soil hydrology and the full coupling of photosynthesis and transpiration through interactive canopy conductance.…”

Section: Overview Of Sedgesmentioning

confidence: 99%

“…Choosing the appropriate level of complexity of represented processes within a land surface or dynamic global vegetation model often depends on the context in which the model is to be used and involves subjective weighting of trade-offs between increased accuracy and realism on the one hand and, on the other hand, robustness to the chosen values of poorly constrained parameters and model reliability in a wide range of situations (Prentice et al, 2015). This paper presents the SEDGES model's structure, equations, and ability to simulate ecological and hydrological variables when used in conjunction with a simple soil hydrological scheme and parameterization for aerodynamic conductance and forced by reanalysis data.…”

Section: Introductionmentioning

confidence: 99%

Description and validation of the Simple, Efficient, Dynamic, Global, Ecological Simulator (SEDGES v.1.0)

Paiewonsky

Timm

2018

Geosci. Model Dev.

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Abstract. In this paper, we present a simple dynamic global vegetation model whose primary intended use is auxiliary to the land-atmosphere coupling scheme of a climate model, particularly one of intermediate complexity. The model simulates and provides important ecological-only variables but also some hydrological and surface energy variables that are typically either simulated by land surface schemes or else used as boundary data input for these schemes. The model formulations and their derivations are presented here, in detail. The model includes some realistic and useful features for its level of complexity, including a photosynthetic dependency on light, full coupling of photosynthesis and transpiration through an interactive canopy resistance, and a soil organic carbon dependence for bare-soil albedo. We evaluate the model's performance by running it as part of a simple land surface scheme that is driven by reanalysis data. The evaluation against observational data includes net primary productivity, leaf area index, surface albedo, and diagnosed variables relevant for the closure of the hydrological cycle. In this setup, we find that the model gives an adequate to good simulation of basic large-scale ecological and hydrological variables. Of the variables analyzed in this paper, gross primary productivity is particularly well simulated. The results also reveal the current limitations of the model. The most significant deficiency is the excessive simulation of evapotranspiration in mid-to high northern latitudes during their winter to spring transition. The model has a relative advantage in situations that require some combination of computational efficiency, model transparency and tractability, and the simulation of the large-scale vegetation and land surface characteristics under non-present-day conditions.

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Strong dependence of CO₂ emissions from anthropogenic land cover change on initial land cover and soil carbon parametrization

Goll

Brovkin

Liski

et al. 2015

Global Biogeochemical Cycles

111

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The quantification of sources and sinks of carbon from land use and land cover changes (LULCC) is uncertain. We investigated how the parametrization of LULCC and of organic matter decomposition, as well as initial land cover, affects the historical and future carbon fluxes in an Earth System Model (ESM). Using the land component of the Max Planck Institute ESM, we found that the historical (1750-2010) LULCC flux varied up to 25% depending on the fraction of biomass which enters the atmosphere directly due to burning or is used in short-lived products. The uncertainty in the decadal LULCC fluxes of the recent past due to the parametrization of decomposition and direct emissions was 0.6 Pg C yr −1 , which is 3 times larger than the uncertainty previously attributed to model and method in general. Preindustrial natural land cover had a larger effect on decadal LULCC fluxes than the aforementioned parameter sensitivity (1.0 Pg C yr −1 ). Regional differences between reconstructed and dynamically computed land covers, in particular, at low latitudes, led to differences in historical LULCC emissions of 84-114 Pg C, globally. This effect is larger than the effects of forest regrowth, shifting cultivation, or climate feedbacks and comparable to the effect of differences among studies in the terminology of LULCC. In general, we find that the practice of calibrating the net land carbon balance to provide realistic boundary conditions for the climate component of an ESM hampers the applicability of the land component outside its primary field of application.

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Reliable, robust and realistic: the three R's of next-generation land-surface modelling

Cited by 194 publications

References 173 publications

Quantification and attribution of errors in the simulated annual gross primary production and latent heat fluxes by two global land surface models

Quantification and attribution of errors in the simulated annual gross primary production and latent heat fluxes by two global land surface models

Description and validation of the Simple, Efficient, Dynamic, Global, Ecological Simulator (SEDGES v.1.0)

Strong dependence of CO₂ emissions from anthropogenic land cover change on initial land cover and soil carbon parametrization

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Reliable, robust and realistic: the three R's of next-generation land-surface modelling

Cited by 194 publications

References 173 publications

Quantification and attribution of errors in the simulated annual gross primary production and latent heat fluxes by two global land surface models

Quantification and attribution of errors in the simulated annual gross primary production and latent heat fluxes by two global land surface models

Description and validation of the Simple, Efficient, Dynamic, Global, Ecological Simulator (SEDGES v.1.0)

Strong dependence of CO2 emissions from anthropogenic land cover change on initial land cover and soil carbon parametrization

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Strong dependence of CO₂ emissions from anthropogenic land cover change on initial land cover and soil carbon parametrization