Global consequences of afforestation and bioenergy cultivation on ecosystem service indicators

Krause, Andreas; Pugh, Thomas A. M.; Bayer, A.; Doelman, Jonathan C.; Humpenöder, Florian; Anthoni, Peter; Olin, Stefan; Bodirsky, Benjamin Leon; Popp, Alexander; Stehfest, Elke; Arneth, Almut

doi:10.5194/bg-14-4829-2017

Cited by 53 publications

(69 citation statements)

References 125 publications

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“…In this study, we only address the uncertainty in land‐based mitigation arising from potential C uptake for a prescribed available area. However, the establishment of negative emissions from land management could also be hindered by unacceptable social or ecological side‐effects (Kartha & Dooley, ; Krause et al., ; Smith, Davis, et al., ), biophysical and biogeochemical climate impacts beyond C (Boysen, Lucht, & Gerten, ; Krause et al., ; Smith, Davis, et al., ), irreversible effects of overshooting CO 2 concentrations (Kartha & Dooley, ; Tokarska & Zickfeld, ), or simply because CCS turns out to be technologically infeasible at commercial scale. There is also strong evidence that the timescales for shifts in farming systems to be realized may be of the order of several decades, substantially delaying the onset of negative emissions from BECCS (Alexander, Moran, Rounsevell, & Smith, ; Brown et al., submitted).…”

Section: Discussionmentioning

confidence: 99%

“…They were derived to match assumed crop yields in the LUMs. A historic hindcast (1901–1969/1901–1994) was calculated based on initial (1970/1995) fertilizer rates from the LUMs and relative changes in the Land‐Use Harmonization data set (http://luh.umd.edu/index.shtml, see also Krause et al., ). The implementation of the LU data into the DGVMs (e.g., mapping to DGVM vegetation types and defining rules by which managed land expands over natural vegetation), land masks, and additional required input variables (e.g., soil characteristics) were left to the responsibility of the individual DGVM groups.…”

Section: Methodsmentioning

confidence: 99%

“…However, the land demand/availability of these approaches is highly uncertain (Boysen, Lucht, & Gerten, ; Popp et al., ), and their potential to remove significant amounts of C from the atmosphere is regarded as controversial (Fuss et al., ). In addition, conflicts with other LU, associated supply of ecosystem services, and maintenance/enhancement of biodiversity are highly likely (Krause et al., ; Smith, Davis, et al., ; Williamson, ). Considering typical time frames of decades involved in the planning and establishment of climate mitigation projects, the quantification of their uncertainties in terms of achievable CDR is important to inform policy makers about practicality and risks.…”

Section: Introductionmentioning

confidence: 99%

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Large uncertainty in carbon uptake potential of land‐based climate‐change mitigation efforts

Krause

Pugh

Bayer

et al. 2018

Global Change Biology

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Most climate mitigation scenarios involve negative emissions, especially those that aim to limit global temperature increase to 2°C or less. However, the carbon uptake potential in land-based climate change mitigation efforts is highly uncertain. Here, we address this uncertainty by using two land-based mitigation scenarios from two land-use models (IMAGE and MAgPIE) as input to four dynamic global vegetation models (DGVMs; LPJ-GUESS, ORCHIDEE, JULES, LPJmL). Each of the four combinations of land-use models and mitigation scenarios aimed for a cumulative carbon uptake of ~130 GtC by the end of the century, achieved either via the cultivation of bioenergy crops combined with carbon capture and storage (BECCS) or avoided deforestation and afforestation (ADAFF). Results suggest large uncertainty in simulated future land demand and carbon uptake rates, depending on the assumptions related to land use and land management in the models. Total cumulative carbon uptake in the DGVMs is highly variable across mitigation scenarios, ranging between 19 and 130 GtC by year 2099. Only one out of the 16 combinations of mitigation scenarios and DGVMs achieves an equivalent or higher carbon uptake than achieved in the land-use models. The large differences in carbon uptake between the DGVMs and their discrepancy against the carbon uptake in IMAGE and MAgPIE are mainly due to different model assumptions regarding bioenergy crop yields and due to the simulation of soil carbon response to land-use change. Differences between land-use models and DGVMs regarding forest biomass and the rate of forest regrowth also have an impact, albeit smaller, on the results. Given the low confidence in simulated carbon uptake for a given land-based mitigation scenario, and that negative emissions simulated by the DGVMs are typically lower than assumed in scenarios consistent with the 2°C target, relying on negative emissions to mitigate climate change is a highly uncertain strategy.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Large uncertainty in carbon uptake potential of land‐based climate‐change mitigation efforts

Krause

Pugh

Bayer

et al. 2018

Global Change Biology

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“…However, we also see low simulated carbon sequestration under constant land use compared to the models in Nishina et al (2015), even when excluding models that did not simulate nitrogen limitation. Other important differences between the runs in Krause et al (2017) and ours include our use of different climate forcings and associated photosynthesis scaling parameters.…”

Section: Carbon Storage 285mentioning

confidence: 99%

“…A substantial body of research has been built up using such models to examine how future land-use change will affect individual ecosystem services such as carbon sequestration (Brovkin et al, 2013;Lawrence et al, 2018), biodiversity (Jantz et al, 2015;Hof et al, 2018;Di Marco et al, 2019), and water availability and flood risk (Davie et al, 2013;Elliott et al, 2014;Asadieh and Krakauer, 2017). Much less work has been undertaken to evaluate 30 the future of a suite of ecosystem services in an integrated way (Krause et al, 2017;Molotoks et al, 2018). However, such analyses provide critically important evidence for balancing the many competing demands on the land system while achieving climate and societal targets such as those laid out in the Paris Agreement and Sustainable Development goals (Eitelberg et al, 2016;Benton et al, 2018;Verhagen et al, 2018).…”

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confidence: 99%

Impacts of future agricultural change on ecosystem service indicators

Rabin¹,

Alexander²,

Henry³

et al. 2019

Preprint

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A future of increasing atmospheric carbon dioxide concentrations, changing climate, growing human populations, and shifting socioeconomic conditions means that the global agricultural system will need to adapt in order to feed the world.These changes will affect not only agricultural land, but terrestrial ecosystems in general. Here, we use the coupled land use and vegetation model LandSyMM to quantify future land use change and resulting impacts on ecosystem service indicators including carbon sequestration, runoff, and nitrogen pollution. We additionally hold certain variables, such as climate or land 5 use, constant to assess the relative contribution of different drivers to the projected impacts. While indicators of some ecosystem services (e.g., flood and drought risk) see trends that are mostly dominated by the direct effects of climate change, others (e.g., carbon sequestration) depend critically on land use and management. Scenarios in which climate change mitigation is more difficult (Shared Socioeconomic Pathways 3 and 5) have the strongest impacts on ecosystem service indicators, such as a loss of 13-19% of land in biodiversity hotspots and a 28% increase in nitrogen pollution. Evaluating a suite of ecosystem service 10 indicators across scenarios enables the identification of tradeoffs and co-benefits associated with different climate change mitigation and adaptation strategies and socioeconomic developments.

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Differences between low-end and high-end climate change impacts in Europe across multiple sectors

et al. 2018

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The Paris Agreement established the 1.5 and 2°C targets based on the recognition Bthat this would significantly reduce the risks and impacts of climate change^. We tested this assertion by comparing impacts at the regional scale between low-end (< 2°C; RCP2.6) and high-end (> 4°C; RCP8.5) climate change scenarios accounting for interactions across six sectors (agriculture, forestry, biodiversity, water, coasts and urban) using an integrated assessment model. Results show that there are only minor differences in most impact indicators for the 2020s time slice, but impacts are considerably greater under high-end than low-end climate change in the 2050s and 2080s. For example, for the 2080s, mitigation consistent with the Paris Agreement would reduce aggregate Europe-wide impacts on the area of intensive agriculture by 21% (on average across climate models), on the area of managed forests by 34%, on water stress by 14%, on people flooded by 10% and on biodiversity vulnerability by 16%. Including socioeconomic scenarios (SSPs 1, 3, 4, 5) results in considerably greater variation in the magnitude, range and direction of change of the majority of impact indicators than climate change alone. In particular, socioeconomic factors much more strongly drive changes in land use and food production than changes in climate, sometimes overriding the differences due to low-end and high-end climate change. Such impacts pose significant challenges for adaptation and highlight the importance of searching for synergies between adaptation and mitigation and linking them to sustainable development goals.

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Global consequences of afforestation and bioenergy cultivation on ecosystem service indicators

Cited by 53 publications

References 125 publications

Large uncertainty in carbon uptake potential of land‐based climate‐change mitigation efforts

Large uncertainty in carbon uptake potential of land‐based climate‐change mitigation efforts

Impacts of future agricultural change on ecosystem service indicators

Differences between low-end and high-end climate change impacts in Europe across multiple sectors

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