Implications of accounting for land use in simulations of ecosystem carbon cycling in Africa

Lindeskog, Mats; Arneth, Almut; Bondeau, Alberte; Waha, Katharina; Seaquist, Jonathan; Olin, Stefan; Smith, Benjamin

doi:10.5194/esd-4-385-2013

Cited by 146 publications

(211 citation statements)

References 73 publications

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“…PLUM can reproduce global historic agricultural land use change , and results have demonstrated that agricultural land use is highly sensitive to uncertainties in crop yield growth rates . To estimate the temporal trends and changes in spatial patterns of crop yields in response to climate change, country-level cereal yields were derived from the global dynamic vegetation model LPJ-GUESS (Lindeskog et al, 2013;Smith et al, 2001). LPJ-GUESS accounts for the effects of temperature, precipitation and atmospheric CO 2 concentrations on crop yields and the productivity of natural vegetation.…”

Section: Plum Simulations -Descriptions Of Future Croplandmentioning

confidence: 99%

“…The direction of socio-economic drivers is referred to as deep uncertainties, which are addressed through the use of scenarios (van Vuuren et al, 2008). Cropland projections at the high end of the projected uncertainty range for global cropland would have profound consequences for, for example, global carbon and nitrogen fluxes, the global water balance, biodiversity, and other ecosystem services (Lindeskog et al, 2013;Pereira et al, 2012;Zaehle et al, 2007). Hence, quantifying and understanding the inherent uncertainties in the drivers of LULCC has important consequences for policy responses to support sustainable development.…”

Section: Introductionmentioning

confidence: 99%

“…The RCP-SSP scenario framework was used since it is the most recent scenario approach for global environmental change research O'Neill et al, 2016;van Vuuren et al, 2011van Vuuren et al, , 2014. We apply these scenarios to a global-scale, socio-economic model of agricultural land use change (the Parsimonious Land Use Model, PLUM; Engström et al, 2016) in combination with crop yield time series derived from the dynamic global vegetation model, LPJ-GUESS (Lund-Potsdam-Jena General Ecosystem Simulator; Lindeskog et al, 2013;Smith et al, 2001). PLUM has been benchmarked against different models and scenario studies in a land use model intercomparison exercise Prestele et al, 2016) that has demonstrated its consistency in comparison with other global cropland simulations.…”

Section: Introductionmentioning

confidence: 99%

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Assessing uncertainties in global cropland futures using a conditional probabilistic modelling framework

et al. 2016

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Abstract. We present a modelling framework to simulate probabilistic futures of global cropland areas that are conditional on the SSP (shared socio-economic pathway) scenarios. Simulations are based on the Parsimonious Land Use Model (PLUM) linked with the global dynamic vegetation model LPJ-GUESS (Lund-Potsdam-Jena General Ecosystem Simulator) using socio-economic data from the SSPs and climate data from the RCPs (representative concentration pathways). The simulated range of global cropland is 893-2380 Mha in 2100 (± 1 standard deviation), with the main uncertainties arising from differences in the socio-economic conditions prescribed by the SSP scenarios and the assumptions that underpin the translation of qualitative SSP storylines into quantitative model input parameters. Uncertainties in the assumptions for population growth, technological change and cropland degradation were found to be the most important for global cropland, while uncertainty in food consumption had less influence on the results. The uncertainties arising from climate variability and the differences between climate change scenarios do not strongly affect the range of global cropland futures. Some overlap occurred across all of the conditional probabilistic futures, except for those based on SSP3. We conclude that completely different socio-economic and climate change futures, although sharing low to medium population development, can result in very similar cropland areas on the aggregated global scale.

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Section: Plum Simulations -Descriptions Of Future Croplandmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Assessing uncertainties in global cropland futures using a conditional probabilistic modelling framework

et al. 2016

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“…Agricultural and pastoral systems are 10 represented as a prescribed fractional cover of area under human land use per grid cell. Four crop functional types modelled on winter wheat, spring wheat, rice, and maize were used to simulate croplands , with representation of sowing, harvesting, irrigation, fertilisation, tillage, and the use of cover crops (Lindeskog et al, 2013;Olin et al, 2015;Pugh et al, 2015). Pastures are represented by competing C3 and C4 grass, with 50% of the above-ground biomass removed annually to 15 represent the effects of grazing (Lindeskog et al, 2013).…”

Section: Case Studymentioning

confidence: 99%

“…Four crop functional types modelled on winter wheat, spring wheat, rice, and maize were used to simulate croplands , with representation of sowing, harvesting, irrigation, fertilisation, tillage, and the use of cover crops (Lindeskog et al, 2013;Olin et al, 2015;Pugh et al, 2015). Pastures are represented by competing C3 and C4 grass, with 50% of the above-ground biomass removed annually to 15 represent the effects of grazing (Lindeskog et al, 2013). A general circulation model (GCM) emulator, IMOGEN, provides feedback between the carbon cycle and climate to be investigated without the computational demands of running a full Earth System Model (Huntingford et al, 2010).…”

Section: Case Studymentioning

confidence: 99%

Modelling feedbacks between human and natural processes in the land system

Robinson¹,

Vittorio²,

Alexander³

et al. 2017

Preprint

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The unprecedented use of Earth's resources by humans, in combination with the increasing natural variability in natural processes over the past century, is affecting evolution of the Earth system. To better understand natural processes and their potential future trajectories requires improved integration with 5 and quantification of human processes. Similarly, to mitigate risk and facilitate socio-economic development requires a better understanding of how the natural system (e.g., climate variability and change, extreme weather events, and processes affecting soil fertility) affects human processes. To capture and formalize our understanding of the interactions and feedback between human and natural systems a variety of modelling approaches are used. While integrated assessment models are widely 10 recognized as supporting this goal and integrating representations of the human and natural system for global applications, an increasing diversity of models and corresponding research have focused on coupling models specializing in specific human (e.g., decision-making) or natural (e.g., erosion) processes at multiple scales. Domain experts develop these specialized models with a greater degree of detail, accuracy, and transparency, with many adopting open-science norms that use new technology for 15 model sharing, coupling, and high performance computing. We highlight examples of four different approaches used to couple representations of the human and natural system, which vary in the processes represented and in the scale of their application. The examples illustrate how groups of researchers have attempted to overcome the lack of suitable frameworks for coupling human and natural systems to answer questions specific to feedbacks between human and natural systems. We draw from these 20 examples broader lessons about system and model coupling and discuss the challenges associated with maintaining consistency across models and representing feedback between human and natural systems in coupled models.Earth Syst. Dynam. Discuss., https://doi

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Effect of climate data on simulated carbon and nitrogen balances for Europe

et al. 2016

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In this study, we systematically assess the spatial variability in carbon and nitrogen balance simulations related to the choice of global circulation models (GCMs), representative concentration pathways (RCPs), spatial resolutions, and the downscaling methods used as calculated with LPJ‐GUESS. We employed a complete factorial design and performed 24 simulations for Europe with different climate input data sets and different combinations of these four factors. Our results reveal that the variability in simulated output in Europe is moderate with 35.6%–93.5% of the total variability being common among all combinations of factors. The spatial resolution is the most important factor among the examined factors, explaining 1.5%–10.7% of the total variability followed by GCMs (0.3%–7.6%), RCPs (0%–6.3%), and downscaling methods (0.1%–4.6%). The higher‐order interactions effect that captures nonlinear relations between the factors and random effects is pronounced and accounts for 1.6%–45.8% to the total variability. The most distinct hot spots of variability include the mountain ranges in North Scandinavia and the Alps, and the Iberian Peninsula. Based on our findings, we advise to conduct the application of models such as LPJ‐GUESS at a reasonably high spatial resolution which is supported by the model structure. There is no notable gain in simulations of ecosystem carbon and nitrogen stocks and fluxes from using regionally downscaled climate in preference to bias‐corrected, bilinearly interpolated CMIP5 projections.

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Implications of accounting for land use in simulations of ecosystem carbon cycling in Africa

Cited by 146 publications

References 73 publications

Assessing uncertainties in global cropland futures using a conditional probabilistic modelling framework

Assessing uncertainties in global cropland futures using a conditional probabilistic modelling framework

Modelling feedbacks between human and natural processes in the land system

Effect of climate data on simulated carbon and nitrogen balances for Europe

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