Your search keyword '"Florian Humpenöder"' showing total 22 results

1. Impact of declining renewable energy costs on electrification in low-emission scenarios

Author

Leon Merfort, Alexander Popp, Lavinia Baumstark, Antoine Levesque, Renato Rodrigues, Nico Bauer, Felix Schreyer, Robert C. Pietzcker, Silvia Madeddu, Falko Ueckerdt, Florian Humpenöder, Elmar Kriegler, Christoph Bertram, Jessica Strefler, Gunnar Luderer, Michaja Pehl, Alois Dirnaichner, and Marianna Rottoli

Subjects

Energy carrier, 010504 meteorology & atmospheric sciences, Renewable Energy, Sustainability and the Environment, business.industry, Natural resource economics, 020209 energy, Global warming, Energy Engineering and Power Technology, Climate change, Carbon dioxide removal, 02 engineering and technology, 01 natural sciences, 7. Clean energy, Electronic, Optical and Magnetic Materials, Renewable energy, Fuel Technology, Electrification, 13. Climate action, Bioenergy, 11. Sustainability, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Electricity, business, 0105 earth and related environmental sciences

Abstract

Cost degression in photovoltaics, wind-power and battery storage has been faster than previously anticipated. In the future, climate policy to limit global warming to 1.5–2 °C will make carbon-based fuels increasingly scarce and expensive. Here we show that further progress in solar- and wind-power technology along with carbon pricing to reach the Paris Climate targets could make electricity cheaper than carbon-based fuels. In combination with demand-side innovation, for instance in e-mobility and heat pumps, this is likely to induce a fundamental transformation of energy systems towards a dominance of electricity-based end uses. In a 1.5 °C scenario with limited availability of bioenergy and carbon dioxide removal, electricity could account for 66% of final energy by mid-century, three times the current levels and substantially higher than in previous climate policy scenarios assessed by the Intergovernmental Panel on Climate Change. The lower production of bioenergy in our high-electrification scenarios markedly reduces energy-related land and water requirements. The impact of rapidly falling costs of renewable energy and battery technology on long-term climate stabilization pathways is not well understood. Luderer et al. show that reduced renewable costs and climate policies will make electricity the cheapest energy carrier and can lead to electricity accounting for nearly two-thirds of global energy use by mid-century.

Published

2021

2. Land-based implications of early climate actions without global net-negative emissions

Author

Anique-Marie Cabardos, Tomoko Hasegawa, Detlef P. van Vuuren, Mykola Gusti, Florian Fosse, Jacques Després, Yuki Ochi, Roberto Schaeffer, Pedro Rochedo, Ken Oshiro, Mathijs Harmsen, Bas van Ruijven, Johannes Emmerling, Petr Havlik, Andre Deppermann, Kimon Keramidas, Alexander Popp, Shinichiro Fujimori, Keywan Riahi, Volker Krey, Stefan Frank, Laurent Drouet, Florian Humpenöder, Christoph Bertram, and Environmental Sciences

Subjects

010504 meteorology & atmospheric sciences, Monitoring, Natural resource economics, Food prices, Geography, Planning and Development, Carbon dioxide removal, Management, Monitoring, Policy and Law, 7. Clean energy, 01 natural sciences, environmental impact, 03 medical and health sciences, 11. Sustainability, Taverne, Ecosystem, Renewable Energy, 030304 developmental biology, 0105 earth and related environmental sciences, agriculture, Nature and Landscape Conservation, 2. Zero hunger, Planning and Development, 0303 health sciences, Global and Planetary Change, Land use, Geography, Sustainability and the Environment, Policy and Law, Ecology, business.industry, Renewable Energy, Sustainability and the Environment, forestry, 15. Life on land, Overshoot (population), sustainability, Management, Energy crop, Urban Studies, climate-change mitigation, 13. Climate action, Agriculture, Food systems, Environmental science, business, Food Science

Abstract

Delaying climate mitigation action and allowing a temporary overshoot of temperature targets require large-scale carbon dioxide removal (CDR) in the second half of this century that may induce adverse side effects on land, food and ecosystems. Meanwhile, meeting climate goals without global net-negative emissions inevitably needs early and rapid emission reduction measures, which also brings challenges in the near term. Here we identify the implications for land-use and food systems of scenarios that do not depend on land-based CDR technologies. We find that early climate action has multiple benefits and trade-offs, and avoids the need for drastic (mitigation-induced) shifts in land use in the long term. Further long-term benefits are lower food prices, reduced risk of hunger and lower demand for irrigation water. Simultaneously, however, near-term mitigation pressures in the agriculture, forest and land-use sector and the required land area for energy crops increase, resulting in additional risk of food insecurity.

Published

2021

3. A sustainable development pathway for climate action within the UN 2030 Agenda

Author

Jan Philipp Dietrich, Marian Leimbach, Constantin Ruhe, Christopher Wingens, Johannes Koch, Matthias Hofmann, David Klein, Felicitas Beier, Alois Dirnaichner, Florian Humpenöder, Christoph Bertram, Jessica Strefler, Robert C. Pietzcker, Hermann Lotze-Campen, Lavinia Baumstark, Alexander Popp, Bjoern Soergel, Julia Leininger, Gunnar Luderer, Nico Bauer, Antoine Levesque, Michaja Pehl, Patrick von Jeetze, Elmar Kriegler, Benjamin Leon Bodirsky, Sebastian Rauner, and Isabelle Weindl

Subjects

Sustainable development, Extreme poverty, 010504 meteorology & atmospheric sciences, Technological change, 1. No poverty, Psychological intervention, Redistribution (cultural anthropology), 010501 environmental sciences, Environmental Science (miscellaneous), Climate Finance, 01 natural sciences, 12. Responsible consumption, 13. Climate action, Political science, 11. Sustainability, Planetary boundaries, Revenue, Environmental planning, Social Sciences (miscellaneous), 0105 earth and related environmental sciences

Abstract

Ambitious climate policies, as well as economic development, education, technological progress and less resource-intensive lifestyles, are crucial elements for progress towards the UN Sustainable Development Goals (SDGs). However, using an integrated modelling framework covering 56 indicators or proxies across all 17 SDGs, we show that they are insufficient to reach the targets. An additional sustainable development package, including international climate finance, progressive redistribution of carbon pricing revenues, sufficient and healthy nutrition and improved access to modern energy, enables a more comprehensive sustainable development pathway. We quantify climate and SDG outcomes, showing that these interventions substantially boost progress towards many aspects of the UN Agenda 2030 and simultaneously facilitate reaching ambitious climate targets. Nonetheless, several important gaps remain; for example, with respect to the eradication of extreme poverty (180 million people remaining in 2030). These gaps can be closed by 2050 for many SDGs while also respecting the 1.5 °C target and several other planetary boundaries. Current action is insufficient to meet both the Paris Agreement and the Sustainable Development Goals. Integrated model-based analysis shows that strong interventions across many dimensions, together with ambitious lifestyle change, are needed to enable real progress towards the UN Agenda 2030.

Published

2021

4. Taking stock of national climate policies to evaluate implementation of the Paris Agreement

Author

Mark Roelfsema, Elmar Kriegler, Zoi Vrontisi, Pedro Rochedo, Daniel Huppmann, Falko Ueckerdt, Gokul Iyer, Saritha Vishwanathan, Oliver Fricko, Michel G.J. den Elzen, Stefan Frank, Matthew Gidden, Keywan Riahi, Jacques Després, Niklas Höhne, Mathijs Harmsen, Volker Krey, Laurent Drouet, Roberto Schaeffer, Gunnar Luderer, Ken Oshiro, Maria Kannavou, Lara Aleluia Reis, Florian Humpenöder, Christoph Bertram, Gabriela Iacobuta, Jae Edmonds, Detlef P. van Vuuren, Wenying Chen, Johannes Emmerling, Kimon Keramidas, Kejun Jiang, Alexandre C. Köberle, Keii Gi, Ritu Mathur, George Safonov, Shinichiro Fujimori, Heleen van Soest, Kostas Fragkiadakis, Environmental Sciences, and Energy, Resources & Technological Change

Subjects

010504 meteorology & atmospheric sciences, Chemistry(all), Science, General Physics and Astronomy, Climate change, Public policy, 010501 environmental sciences, Physics and Astronomy(all), 7. Clean energy, 01 natural sciences, Biochemistry, General Biochemistry, Genetics and Molecular Biology, Article, 11. Sustainability, Life Science, Scenario analysis, Emerging markets, lcsh:Science, Climate-change mitigation, Stock (geology), 0105 earth and related environmental sciences, Multidisciplinary, WIMEK, Biochemistry, Genetics and Molecular Biology(all), Climate-change policy, General Chemistry, Environmental economics, Climate change mitigation, Environmental Systems Analysis, 13. Climate action, Milieusysteemanalyse, Renewable technologies, lcsh:Q, Business, Genetics and Molecular Biology(all)

Abstract

Many countries have implemented national climate policies to accomplish pledged Nationally Determined Contributions and to contribute to the temperature objectives of the Paris Agreement on climate change. In 2023, the global stocktake will assess the combined effort of countries. Here, based on a public policy database and a multi-model scenario analysis, we show that implementation of current policies leaves a median emission gap of 22.4 to 28.2 GtCO2eq by 2030 with the optimal pathways to implement the well below 2 °C and 1.5 °C Paris goals. If Nationally Determined Contributions would be fully implemented, this gap would be reduced by a third. Interestingly, the countries evaluated were found to not achieve their pledged contributions with implemented policies (implementation gap), or to have an ambition gap with optimal pathways towards well below 2 °C. This shows that all countries would need to accelerate the implementation of policies for renewable technologies, while efficiency improvements are especially important in emerging countries and fossil-fuel-dependent countries., To evaluate the effectiveness of current national policies in achieving global temperature targets is important but a systematic multi-model evaluation is still lacking. Here the authors identified a reduction of 3.5 GtCO2 eq of current national policies relative to a baseline scenario without climate policies by 2030 due to the increasing low carbon share of final energy and the improving final energy intensity.

Published

2020

5. Bending the curve of terrestrial biodiversity needs an integrated strategy

Author

Bernardo B. N. Strassburg, Wenchao Wu, Petr Havlik, Stuart H. M. Butchart, Deon Nel, Andrzej Tabeau, Andrew J. Hoskins, Hermann Lotze-Campen, Guido Schmidt-Traub, Tetsuya Matsui, Tamás Krisztin, Alexander Popp, Fulvio Di Fulvio, Mario Herrero, Fabrice DeClerck, M. Grooten, Chris Ware, Carsten Meyer, Adriana De Palma, Neil D. Burgess, Simon Ferrier, Rob Alkemade, Hans van Meijl, L. Young, Georgina M. Mace, Rosamunde E. A. Almond, Samantha L. L. Hill, Jonathan C. Doelman, Abhishek Chaudhary, Shinichiro Fujimori, Robin Freeman, Michael Obersteiner, Tom Harwood, Detlef P. van Vuuren, Aafke M. Schipper, M. Barrett, David Leclère, Nancy Jennings, Tim Newbold, Andy Purvis, M. Dürauer, Florian Humpenöder, Elke Stehfest, G. Bunting, Tom Kram, Stefanie Hellweg, Willem-Jan van Zeist, Steffen Fritz, Sarah Cornell, Mike Harfoot, Martin Jung, Haruka Ohashi, Moreno Di Marco, Piero Visconti, Hugo Valin, Tomoko Hasegawa, Jelle P. Hilbers, James E. M. Watson, and Environmental Sciences

Subjects

0106 biological sciences, Conservation of Natural Resources, 010504 meteorology & atmospheric sciences, Natural resource economics, Population, Food prices, Biodiversity, 010603 evolutionary biology, 01 natural sciences, 12. Responsible consumption, Ecosystem services, Food Supply, Environmental impact, 11. Sustainability, Taverne, Agricultural Economics and Rural Policy, Life Science, Humans, Human Activities, International Policy, education, Internationaal Beleid, 0105 earth and related environmental sciences, 2. Zero hunger, education.field_of_study, Multidisciplinary, business.industry, Programmamanagement, Diet, Vegetarian, Agrarische Economie en Plattelandsbeleid, Agriculture, 15. Life on land, Sustainable Development, Diet, Environmental Policy, Environmental Systems Analysis, Habitat, 13. Climate action, Milieusysteemanalyse, Sustainability, Food systems, business, Environmental Sciences

Abstract

Increased efforts are required to prevent further losses to terrestrial biodiversity and the ecosystem services that it provides1,2. Ambitious targets have been proposed, such as reversing the declining trends in biodiversity3; however, just feeding the growing human population will make this a challenge4. Here we use an ensemble of land-use and biodiversity models to assess whether—and how—humanity can reverse the declines in terrestrial biodiversity caused by habitat conversion, which is a major threat to biodiversity5. We show that immediate efforts, consistent with the broader sustainability agenda but of unprecedented ambition and coordination, could enable the provision of food for the growing human population while reversing the global terrestrial biodiversity trends caused by habitat conversion. If we decide to increase the extent of land under conservation management, restore degraded land and generalize landscape-level conservation planning, biodiversity trends from habitat conversion could become positive by the mid-twenty-first century on average across models (confidence interval, 2042–2061), but this was not the case for all models. Food prices could increase and, on average across models, almost half (confidence interval, 34–50%) of the future biodiversity losses could not be avoided. However, additionally tackling the drivers of land-use change could avoid conflict with affordable food provision and reduces the environmental effects of the food-provision system. Through further sustainable intensification and trade, reduced food waste and more plant-based human diets, more than two thirds of future biodiversity losses are avoided and the biodiversity trends from habitat conversion are reversed by 2050 for almost all of the models. Although limiting further loss will remain challenging in several biodiversity-rich regions, and other threats—such as climate change—must be addressed to truly reverse the declines in biodiversity, our results show that ambitious conservation efforts and food system transformation are central to an effective post-2020 biodiversity strategy. To promote the recovery of the currently declining global trends in terrestrial biodiversity, increases in both the extent of land under conservation management and the sustainability of the global food system from farm to fork are required.

Published

2020

6. Critical adjustment of land mitigation pathways for assessing countries’ climate progress

Author

Sandro Federici, Joeri Rogelj, Detlef P. van Vuuren, Alessandro Cescatti, Petr Havlik, Elke Stehfest, Gert-Jan Nabuurs, Francesco N. Tubiello, Simone Rossi, Shinichiro Fujimori, Jo House, Tomoko Hasegawa, Guido Ceccherini, Anu Korosuo, Giacomo Grassi, Alexander Popp, Ramdane Alkama, Katherine Calvin, Florian Humpenöder, Raúl Abad Viñas, Mykola Gusti, Lucia Perugini, and Environmental Sciences

Subjects

010504 meteorology & atmospheric sciences, Natural resource economics, Bos- en Landschapsecologie, Environmental Science (miscellaneous), 01 natural sciences, 03 medical and health sciences, 11. Sustainability, Taverne, Life Science, Forest and Landscape Ecology, 0502 Environmental Science and Management, Vegetatie, 030304 developmental biology, 0105 earth and related environmental sciences, 0303 health sciences, Vegetation, Land use, Global warming, Biogeochemistry, PE&RC, 13. Climate action, Greenhouse gas, Environmental science, Vegetatie, Bos- en Landschapsecologie, 0401 Atmospheric Sciences, Vegetation, Forest and Landscape Ecology, 0406 Physical Geography and Environmental Geoscience, Social Sciences (miscellaneous)

Abstract

Mitigation pathways by Integrated Assessment Models (IAMs) describe future emissions that keep global warming below specific temperature limits and are compared with countries’ collective greenhouse gas (GHG) emission reduction pledges. This is needed to assess mitigation progress and inform emission targets under the Paris Agreement. Currently, however, a mismatch of ~5.5 GtCO2 yr−1 exists between the global land-use fluxes estimated with IAMs and from countries’ GHG inventories. Here we present a ‘Rosetta stone’ adjustment to translate IAMs’ land-use mitigation pathways to estimates more comparable with GHG inventories. This does not change the original decarbonization pathways, but reallocates part of the land sink to be consistent with GHG inventories. Adjusted cumulative emissions over the period until net zero for 1.5 or 2 °C limits are reduced by 120–192 GtCO2 relative to the original IAM pathways. These differences should be taken into account to ensure an accurate assessment of progress towards the Paris Agreement. There is a mismatch between emission estimates from global land use calculated from IAMs and countries’ greenhouse gas inventories. This study presents a method for reconciling these estimates by reallocating part of the land-use sink, facilitating progress assessment towards climate goals.

Published

2021

7. Mitigation Strategies for Greenhouse Gas Emissions from Agriculture and Land-Use Change: Consequences for Food Prices

Author

Jan Philipp Dietrich, Benjamin Leon Bodirsky, Hermann Lotze-Campen, Xiaoxi Wang, Christoph Müller, Miodrag Stevanovic, Anne Biewald, Florian Humpenöder, Ulrich Kreidenweis, Isabelle Weindl, Alexander Popp, and Susanne Rolinski

Subjects

Greenhouse Effect, Conservation of Natural Resources, 010504 meteorology & atmospheric sciences, Climate Change, Food prices, 010501 environmental sciences, 01 natural sciences, Agricultural economics, Food Supply, 12. Responsible consumption, 11. Sustainability, Animals, Environmental Chemistry, Land use, land-use change and forestry, 0105 earth and related environmental sciences, 2. Zero hunger, Food security, Land use, business.industry, 1. No poverty, Agriculture, Forestry, General Chemistry, 15. Life on land, Incentive, Climate change mitigation, 13. Climate action, Greenhouse gas, business

Abstract

The land use sector of agriculture, forestry, and other land use (AFOLU) plays a central role in ambitious climate change mitigation efforts. Yet, mitigation policies in agriculture may be in conflict with food security related targets. Using a global agro-economic model, we analyze the impacts on food prices under mitigation policies targeting either incentives for producers (e.g., through taxes) or consumer preferences (e.g., through education programs). Despite having a similar reduction potential of 43-44% in 2100, the two types of policy instruments result in opposite outcomes for food prices. Incentive-based mitigation, such as protecting carbon-rich forests or adopting low-emission production techniques, increase land scarcity and production costs and thereby food prices. Preference-based mitigation, such as reduced household waste or lower consumption of animal-based products, decreases land scarcity, prevents emissions leakage, and concentrates production on the most productive sites and consequently lowers food prices. Whereas agricultural emissions are further abated in the combination of these mitigation measures, the synergy of strategies fails to substantially lower food prices. Additionally, we demonstrate that the efficiency of agricultural emission abatement is stable across a range of greenhouse-gas (GHG) tax levels, while resulting food prices exhibit a disproportionally larger spread.

Published

2016

8. Key determinants of global land-use projections

Author

Willem-Jan van Zeist, Page Kyle, Andrzej Tabeau, Jonathan C. Doelman, Hermann Lotze-Campen, Daniel Mason-D'Croz, Shinichiro Fujimori, Katherine Calvin, Florian Humpenöder, Petr Havlik, Hans van Meijl, Alexander Popp, Keith Wiebe, Elke Stehfest, Hugo Valin, Tomoko Hasegawa, Benjamin Leon Bodirsky, and Environmental Sciences

Subjects

0301 basic medicine, Natural resource economics, Science, Population, General Physics and Astronomy, 02 engineering and technology, General Biochemistry, Genetics and Molecular Biology, Article, Environmental impact, 03 medical and health sciences, Empirical research, Economics, Agricultural Economics and Rural Policy, Life Science, International Policy, Agricultural productivity, education, lcsh:Science, Internationaal Beleid, Climate-change mitigation, 2. Zero hunger, Sustainable development, Consumption (economics), education.field_of_study, Socioeconomic scenarios, Multidisciplinary, Food security, Land use, Programmamanagement, Agrarische Economie en Plattelandsbeleid, General Chemistry, 15. Life on land, 021001 nanoscience & nanotechnology, 030104 developmental biology, Climate change mitigation, 13. Climate action, lcsh:Q, 0210 nano-technology

Abstract

Land use is at the core of various sustainable development goals. Long-term climate foresight studies have structured their recent analyses around five socio-economic pathways (SSPs), with consistent storylines of future macroeconomic and societal developments; however, model quantification of these scenarios shows substantial heterogeneity in land-use projections. Here we build on a recently developed sensitivity approach to identify how future land use depends on six distinct socio-economic drivers (population, wealth, consumption preferences, agricultural productivity, land-use regulation, and trade) and their interactions. Spread across models arises mostly from diverging sensitivities to long-term drivers and from various representations of land-use regulation and trade, calling for reconciliation efforts and more empirical research. Most influential determinants for future cropland and pasture extent are population and agricultural efficiency. Furthermore, land-use regulation and consumption changes can play a key role in reducing both land use and food-security risks, and need to be central elements in sustainable development strategies., There lacks model comparison of global land use change projections. Here the authors explored how different long-term drivers determine land use and food availability projections and they showed that the key determinants population growth and improvements in agricultural efficiency.

Published

2018

9. Scenarios towards limiting global mean temperature increase below 1.5 °C

Author

Jae Edmonds, Giacomo Marangoni, Massimo Tavoni, Elke Stehfest, Jonathan C. Doelman, Mathijs Harmsen, David E.H.J. Gernaat, Joeri Rogelj, Katherine Calvin, Florian Humpenöder, Jessica Strefler, Detlef P. van Vuuren, Alexander Popp, Tomoko Hasegawa, Keywan Riahi, Shinichiro Fujimori, Gunnar Luderer, Oliver Fricko, Volker Krey, Elmar Kriegler, Laurent Drouet, Johannes Emmerling, Petr Havlik, and Environmental Sciences

Subjects

Socioeconomic scenarios, Environmental Science (miscellaneous), Social Sciences (miscellaneous), 010504 meteorology & atmospheric sciences, 010501 environmental sciences, Environmental economics, Radiative forcing, Energy modelling, 7. Clean energy, 01 natural sciences, Energy and society, Climate change mitigation, Resource (project management), 13. Climate action, restrict, Taverne, Environmental science, Climate model, Limit (mathematics), Mean radiant temperature, Baseline (configuration management), Climate-change mitigation, 0105 earth and related environmental sciences

Abstract

The 2015 Paris Agreement calls for countries to pursue efforts to limit global-mean temperature rise to 1.5 °C. The transition pathways that can meet such a target have not, however, been extensively explored. Here we describe scenarios that limit end-of-century radiative forcing to 1.9 W m−2, and consequently restrict median warming in the year 2100 to below 1.5 °C. We use six integrated assessment models and a simple climate model, under different socio-economic, technological and resource assumptions from five Shared Socio-economic Pathways (SSPs). Some, but not all, SSPs are amenable to pathways to 1.5 °C. Successful 1.9 W m−2 scenarios are characterized by a rapid shift away from traditional fossil-fuel use towards large-scale low-carbon energy supplies, reduced energy use, and carbon-dioxide removal. However, 1.9 W m−2 scenarios could not be achieved in several models under SSPs with strong inequalities, high baseline fossil-fuel use, or scattered short-term climate policy. Further research can help policy-makers to understand the real-world implications of these scenarios.

Published

2018

10. Decoupling Livestock from Land Use through Industrial Feed Production Pathways

Author

Florian Humpenöder, Nico Boon, Hannah H. E. van Zanten, Korneel Rabaey, Silvio Matassa, Ilje Pikaar, Isabelle Weindl, Zhiguo Yuan, Alexander Popp, Michele Bruschi, Mario Herrero, Benjamin Leon Bodirsky, Willy Verstraete, Pikaar, I., Matassa, S., Bodirsky, B. L., Weindl, I., and Humpen

Subjects

Livestock, 010504 meteorology & atmospheric sciences, Animal feed, Industrial production, 010501 environmental sciences, 7. Clean energy, 01 natural sciences, Animal Production Systems, Greenhouse Gases, Environmental protection, Environmental Chemistry, Animals, Industry, Life Science, Nitrogen cycle, 0105 earth and related environmental sciences, 2. Zero hunger, Dierlijke Productiesystemen, business.industry, Agriculture, General Chemistry, 15. Life on land, Animal Feed, 13. Climate action, Plant protein, Greenhouse gas, Nutrient pollution, WIAS, Environmental science, business

Abstract

One of the main challenges for the 21st century is to balance the increasing demand for high-quality proteins while mitigating environmental impacts. In particular, cropland-based production of protein-rich animal feed for livestock rearing results in large-scale agricultural land-expansion, nitrogen pollution, and greenhouse gas emissions. Here we propose and analyze the long-term potential of alternative animal feed supply routes based on industrial production of microbial proteins (MP). Our analysis reveals that by 2050, MP can replace, depending on socio-economic development and MP production pathways, between 10-19% of conventional crop-based animal feed protein demand. As a result, global cropland area, global nitrogen losses from croplands and agricultural greenhouse gas emissions can be decreased by 6% (0-13%), 8% (-3-8%), and 7% (-6-9%), respectively. Interestingly, the technology to industrially produce MP at competitive costs is directly accessible for implementation and has the potential to cause a major structural change in the agro-food system.

Published

2018

11. Land-Use and Carbon Cycle Responses to Moderate Climate Change: Implications for Land-Based Mitigation?

Author

Alexander Popp, Susanne Rolinski, Anne Biewald, Jan Philipp Dietrich, Hermann Lotze-Campen, Miodrag Stevanovic, Benjamin Leon Bodirsky, Florian Humpenöder, Markus Bonsch, Christoph Müller, and Isabelle Weindl

Subjects

Carbon Sequestration, Time Factors, 010504 meteorology & atmospheric sciences, Natural resource economics, Climate Change, Climate change, 010501 environmental sciences, Carbon sequestration, 01 natural sciences, Carbon Cycle, Carbon cycle, Deforestation, Environmental Chemistry, Afforestation, Land use, land-use change and forestry, 0105 earth and related environmental sciences, 2. Zero hunger, Land use, Ecology, Biosphere, Agriculture, General Chemistry, Carbon Dioxide, 15. Life on land, Carbon, 13. Climate action, Environmental science

Abstract

Climate change has impacts on agricultural yields, which could alter cropland requirements and hence deforestation rates. Thus, land-use responses to climate change might influence terrestrial carbon stocks. Moreover, climate change could alter the carbon storage capacity of the terrestrial biosphere and hence the land-based mitigation potential. We use a global spatially explicit economic land-use optimization model to (a) estimate the mitigation potential of a climate policy that provides economic incentives for carbon stock conservation and enhancement, (b) simulate land-use and carbon cycle responses to moderate climate change (RCP2.6), and (c) investigate the combined effects throughout the 21st century. The climate policy immediately stops deforestation and strongly increases afforestation, resulting in a global mitigation potential of 191 GtC in 2100. Climate change increases terrestrial carbon stocks not only directly through enhanced carbon sequestration (62 GtC by 2100) but also indirectly through less deforestation due to higher crop yields (16 GtC by 2100). However, such beneficial climate impacts increase the potential of the climate policy only marginally, as the potential is already large under static climatic conditions. In the broader picture, this study highlights the importance of land-use dynamics for modeling carbon cycle responses to climate change in integrated assessment modeling.

Published

2015

12. Fossil-fueled development (SSP5): an energy and resource intensive scenario for the 21st century

Author

Katherine Calvin, Lavinia Baumstark, Jana Schwanitz, Shinichiro Fujimori, Florian Humpenöder, Christoph Bertram, Jessica Strefler, Benjamin Leon Bodirsky, Anne Biewald, Johannes Emmerling, Ioanna Mouratiadou, Jérôme Hilaire, Ulrich Kreidenweis, Jan Philipp Dietrich, Nico Bauer, Isabelle Weindl, Anselm Schultes, Michaja Pehl, Gunnar Luderer, David Klein, Elmar Kriegler, Markus Bonsch, Miodrag Stevanovic, Robert C. Pietzcker, Alexander Popp, Franziska Piontek, Anastasis Giannousakis, Christoph Müller, Ottmar Edenhofer, Marian Leimbach, Susanne Rolinski, Hermann Lotze-Campen, Biobased Economy, and Energy and Resources

Subjects

Resource (biology), 020209 energy, Geography, Planning and Development, Land-use change, 02 engineering and technology, Management, Monitoring, Policy and Law, 7. Clean energy, 12. Responsible consumption, Shared Socio-economic Pathway, valorisation, 11. Sustainability, 0202 electrical engineering, electronic engineering, information engineering, ddc:550, ddc:333, Baseline (configuration management), 2. Zero hunger, Sustainable development, Global and Planetary Change, Energy demand, Ecology, business.industry, Fossil fuel, Environmental resource management, Radiative forcing, Energy transformation, Integrated assessment modeling, 13. Climate action, Greenhouse gas, SSP5, Emission scenario, Environmental science, business, Energy (signal processing)

Abstract

This paper presents a set of energy and resource intensive scenarios based on the concept of Shared Socio-Economic Pathways (SSPs). The scenario family is characterized by rapid and fossil-fueled development with high socio-economic challenges to mitigation and low socio-economic challenges to adaptation (SSP5). A special focus is placed on the SSP5 marker scenario developed by the REMIND-MAgPIE integrated assessment modeling framework. The SSP5 baseline scenarios exhibit very high levels of fossil fuel use, up to a doubling of global food demand, and up to a tripling of energy demand and greenhouse gas emissions over the course of the century, marking the upper end of the scenario literature in several dimensions. These scenarios are currently the only SSP scenarios that result in a radiative forcing pathway as high as the highest Representative Concentration Pathway (RCP8.5). This paper further investigates the direct impact of mitigation policies on the SSP5 energy, land and emissions dynamics confirming high socio-economic challenges to mitigation in SSP5. Nonetheless, mitigation policies reaching climate forcing levels as low as in the lowest Representative Concentration Pathway (RCP2.6) are accessible in SSP5. The SSP5 scenarios presented in this paper aim to provide useful reference points for future climate change, climate impact, adaption and mitigation analysis, and broader questions of sustainable development.

Published

2017

13. Global consequences of afforestation and bioenergy cultivation on ecosystem service indicators

Author

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

Subjects

2. Zero hunger, Earth sciences, 13. Climate action, ddc:550, 15. Life on land

Abstract

Land management for carbon storage is discussed as being indispensable for climate change mitigation because of its large potential to remove carbon dioxide from the atmosphere, and to avoid further emissions from deforestation. However, land-based mitigation's prospect of success depends on potential side-effects on important ecosystem services. Here, we use projections of future land use and land cover for different land-based mitigation options from two land-use models (IMAGE and MAgPIE) and evaluate their effects with a global dynamic vegetation model (LPJ-GUESS). In the land-use models, a cumulative carbon removal target of 130 GtC by the end of the 21st century was set to be achieved either via growth of bioenergy crops combined with carbon capture and storage, via avoided deforestation and afforestation, or via a combination of both. We compare these scenarios to a reference scenario without land-based mitigation and analyse the LPJ-GUESS simulations with the aim to assess synergies and trade-offs across a range of ecosystem service indicators: carbon sequestration, surface albedo, evapotranspiration, water runoff, crop production, nitrogen loss, and emissions of biogenic volatile organic compounds. In our mitigation simulations carbon removal by year 2099 ranged between 55 and 89 GtC, and thus lower than the removal simulated by the land-use models. Other ecosystem service indicators were influenced heterogeneously both positively and negatively, with large variability across regions and land-use scenarios. Avoided deforestation and afforestation led to an increase in evapotranspiration and enhanced emissions of biogenic volatile organic compounds, and to a decrease in albedo, runoff, and nitrogen loss. Also crop production decreased in the afforestation scenario as a result of reduced crop area, especially for MAgPIE land-use patterns. Bioenergy-based climate change mitigation was projected to affect less area globally than in the forest expansion scenarios, and resulted in less pronounced changes in most ecosystem service indicators than forest-based mitigation, but included a decrease in crop production, nitrogen loss and biogenic volatile organic compounds emissions.

Published

2017

14. Livestock and human use of land: Productivity trends and dietary choices as drivers of future land and carbon dynamics

Author

Miodrag Stevanovic, Alexander Popp, Florian Humpenöder, Anne Biewald, Jan Philipp Dietrich, Isabelle Weindl, Susanne Rolinski, Benjamin Leon Bodirsky, and Hermann Lotze-Campen

Subjects

2. Zero hunger, Global and Planetary Change, 010504 meteorology & atmospheric sciences, Land use, Agroforestry, business.industry, Natural resource economics, 04 agricultural and veterinary sciences, 15. Life on land, Oceanography, 01 natural sciences, 12. Responsible consumption, 13. Climate action, Agricultural land, Deforestation, Greenhouse gas, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental science, Livestock, Land use, land-use change and forestry, Agricultural productivity, business, Productivity, 0105 earth and related environmental sciences

Abstract

Land use change has been the primary driving force of human alteration of terrestrial ecosystems. With 80% of agricultural land dedicated to livestock production, the sector is an important lever to attenuate land requirements for food production and carbon emissions from land use change. In this study, we quantify impacts of changing human diets and livestock productivity on land dynamics and depletion of carbon stored in vegetation, litter and soils. Across all investigated productivity pathways, lower consumption of livestock products can substantially reduce deforestation (47–55%) and cumulative carbon losses (34–57%). On the supply side, already minor productivity growth in extensive livestock production systems leads to substantial CO 2 emission abatement, but the emission saving potential of productivity gains in intensive systems is limited, also involving trade-offs with soil carbon stocks. If accounting for uncertainties related to future trade restrictions, crop yields and pasture productivity, the range of projected carbon savings from changing diets increases to 23–78%. Highest abatement of carbon emissions (63–78%) can be achieved if reduced consumption of animal-based products is combined with sustained investments into productivity increases in plant production. Our analysis emphasizes the importance to integrate demand- and supply-side oriented mitigation strategies and to combine efforts in the crop and livestock sector to enable synergies for climate protection.

Published

2017

15. Land-use futures in the shared socio-economic pathways

Author

Oliver Fricko, Alexander Popp, Isabelle Weindl, Jan Philipp Dietrich, Hermann Lotze-Campen, Katherine Calvin, Andrzej Tabeau, Stephanie Waldhoff, Elmar Kriegler, Jonathan C. Doelmann, Kiyoshi Takahashi, Petr Havlik, Hugo Valin, Shinichiro Fujimori, Marshall Wise, Page Kyle, Tomoko Hasegawa, Florian Humpenöder, Mykola Gusti, Keywan Riahi, Benjamin Leon Bodirsky, Elke Stehfest, Michael Obersteiner, Detlef P. van Vuuren, and Environmental Sciences

Subjects

010504 meteorology & atmospheric sciences, Mitigation, Geography, Planning and Development, Food prices, 010501 environmental sciences, Management, Monitoring, Policy and Law, 01 natural sciences, 12. Responsible consumption, Agricultural land, Scenarios, 11. Sustainability, Land use, land-use change and forestry, Integrated assessment, International Policy, Agricultural productivity, Internationaal Beleid, 0105 earth and related environmental sciences, 2. Zero hunger, Global and Planetary Change, Food security, Ecology, Land use, SSP, business.industry, Environmental resource management, 15. Life on land, Climate change mitigation, 13. Climate action, Emissions, Greenhouse gas, Environmental science, business

Abstract

In the future, the land system will be facing new intersecting challenges. While food demand, especially for resource-intensive livestock based commodities, is expected to increase, the terrestrial system has large potentials for climate change mitigation through improved agricultural management, providing biomass for bioenergy, and conserving or even enhancing carbon stocks of ecosystems. However, uncertainties in future socio-economic land use drivers may result in very different land-use dynamics and consequences for land-based ecosystem services. This is the first study with a systematic interpretation of the Shared Socio-Economic Pathways (SSPs) in terms of possible land-use changes and their consequences for the agricultural system, food provision and prices as well as greenhouse gas emissions. Therefore, five alternative Integrated Assessment Models with distinctive land-use modules have been used for the translation of the SSP narratives into quantitative projections. The model results reflect the general storylines of the SSPs and indicate a broad range of potential land-use futures with global agricultural land of 4900 mio ha in 2005 decreasing by 743 mio ha until 2100 at the lower (SSP1) and increasing by 1080 mio ha (SSP3) at the upper end. Greenhouse gas emissions from land use and land use change, as a direct outcome of these diverse land-use dynamics, and agricultural production systems differ strongly across SSPs (e.g. cumulative land use change emissions between 2005 and 2100 range from −54 to 402 Gt CO2). The inclusion of land-based mitigation efforts, particularly those in the most ambitious mitigation scenarios, further broadens the range of potential land futures and can strongly affect greenhouse gas dynamics and food prices. In general, it can be concluded that low demand for agricultural commodities, rapid growth in agricultural productivity and globalized trade, all most pronounced in a SSP1 world, have the potential to enhance the extent of natural ecosystems, lead to lowest greenhouse gas emissions from the land system and decrease food prices over time. The SSP-based land use pathways presented in this paper aim at supporting future climate research and provide the basis for further regional integrated assessments, biodiversity research and climate impact analysis.

Published

2017

16. Trade-offs between land and water requirements for large-scale bioenergy production

Author

Alexander Popp, Susanne Rolinski, Anne Biewald, Dieter Gerten, Benjamin Leon Bodirsky, Florian Humpenöder, Markus Bonsch, Isabelle Weindl, Jan Philipp Dietrich, Miodrag Stevanovic, and Hermann Lotze-Campen

Subjects

2. Zero hunger, 010504 meteorology & atmospheric sciences, Renewable Energy, Sustainability and the Environment, Agroforestry, Natural resource economics, Carbon dioxide equivalent, Forestry, Energy mix, 010501 environmental sciences, 15. Life on land, 01 natural sciences, 7. Clean energy, 12. Responsible consumption, Water resources, Climate change mitigation, 13. Climate action, Bioenergy, Greenhouse gas, 11. Sustainability, Sustainability, Farm water, Environmental science, Waste Management and Disposal, Agronomy and Crop Science, 0105 earth and related environmental sciences

Abstract

Bioenergy is expected to play an important role in the future energy mix as it can substitute fossil fuels and contribute to climate change mitigation. However, large-scale bioenergy cultivation may put substantial pressure on land and water resources. While irrigated bioenergy production can reduce the pressure on land due to higher yields, associated irrigation water requirements may lead to degradation of freshwater ecosystems and to conflicts with other potential users. In this article, we investigate the trade-offs between land and water requirements of large-scale bioenergy production. To this end, we adopt an exogenous demand trajectory for bioenergy from dedicated energy crops, targeted at limiting greenhouse gas emissions in the energy sector to 1100 Gt carbon dioxide equivalent until 2095. We then use the spatially explicit global land- and water-use allocation model MAgPIE to project the implications of this bioenergy target for global land and water resources. We find that producing 300 EJ yr 1 of bioenergy in 2095 from dedicated bioenergy crops is likely to double agricultural water withdrawals if no explicit water protection policies are implemented. Since current human water withdrawals are dominated by agriculture and already lead to ecosystem degradation and biodiversity loss, such a doubling will pose a severe threat to freshwater ecosystems. If irrigated bioenergy production is prohibited to prevent negative impacts of bioenergy cultivation on water resources, bioenergy land requirements for meeting a 300 EJ yr 1 bioenergy target increase substantially (+ 41%) – mainly at the expense of pasture areas and tropical forests. Thus, avoiding negative environmental impacts of large-scale bioenergy production will require policies that balance associated water and land requirements.

Published

2014

17. A multi-model assessment of food security implications of climate change mitigation

Author

Oliver Fricko, Jacques Després, Yuki Ochi, Johannes Emmerling, Jessica Callen, Keywan Riahi, Florian Humpenöder, Christoph Bertram, Benjamin Leon Bodirsky, Stefan Frank, Volker Krey, Tomoko Hasegawa, Jonathan C. Doelman, Alexander Popp, Valentina Bosetti, Laurent Drouet, Andreas Schmitz, Hans van Meijl, Petr Havlik, Jason F.L. Koopman, Detlef P. van Vuuren, Kiyoshi Takahashi, Shinichiro Fujimori, and Environmental Sciences

Subjects

010504 meteorology & atmospheric sciences, Natural resource economics, Yield (finance), CLIMATE CHANGE, Geography, Planning and Development, Climate change, 010501 environmental sciences, Management, Monitoring, Policy and Law, 01 natural sciences, Gross domestic product, 12. Responsible consumption, SUSTAINABILITY, 11. Sustainability, Taverne, Agricultural Economics and Rural Policy, Life Science, International Policy, Internationaal Beleid, 0105 earth and related environmental sciences, Nature and Landscape Conservation, 2. Zero hunger, Sustainable development, Global and Planetary Change, Food security, FOOD POVERTY, Ecology, Renewable Energy, Sustainability and the Environment, business.industry, Programmamanagement, 1. No poverty, Agrarische Economie en Plattelandsbeleid, Urban Studies, Climate change mitigation, 13. Climate action, Agriculture, Sustainability, Business, SUSTAINABILITY, CLIMATE CHANGE, FOOD POVERTY, Food Science

Abstract

Holding the global increase in temperature caused by climate change well below 2 °C above pre-industrial levels, the goal affirmed by the Paris Agreement, is a major societal challenge. Meanwhile, food security is a high-priority area in the UN Sustainable Development Goals, which could potentially be adversely affected by stringent climate mitigation. Here we show the potential negative trade-offs between food security and climate mitigation using a multi-model comparison exercise. We find that carelessly designed climate mitigation policies could increase the number of people at risk of hunger by 160 million in 2050. Avoiding these adverse side effects would entail a cost of about 0.18% of global gross domestic product in 2050. It should be noted that direct impacts of climate change on yields were not assessed and that the direct benefits from mitigation in terms of avoided yield losses could be substantial, further reducing the above cost. Although results vary across models and model implementations, the qualitative implications are robust and call for careful design of climate mitigation policies taking into account agriculture and land prices.

Published

2019

18. The value of bioenergy in low stabilization scenarios: an assessment using REMIND-MAgPIE

Author

Alexander Popp, Jan Philipp Dietrich, David Klein, Florian Humpenöder, Jessica Strefler, Ottmar Edenhofer, Marian Leimbach, Elmar Kriegler, Nico Bauer, Gunnar Luderer, and Hermann Lotze-Campen

Subjects

Atmospheric Science, Global and Planetary Change, business.industry, Natural resource economics, Fossil fuel, Biomass, Bio-energy with carbon capture and storage, Carbon sequestration, 7. Clean energy, 12. Responsible consumption, 13. Climate action, Bioenergy, Biofuel, 11. Sustainability, Economics, Carbon capture and storage, Production (economics), business

Abstract

This study investigates the use of bioenergy for achieving stringent climate stabilization targets and it analyzes the economic drivers behind the choice of bioenergy technologies. We apply the integrated assessment framework REMIND-MAgPIE to show that bioenergy, particularly if combined with carbon capture and storage (CCS) is a crucial mitigation option with high deployment levels and high technology value. If CCS is available, bioenergy is exclusively used with CCS. We find that the ability of bioenergy to provide negative emissions gives rise to a strong nexus between biomass prices and carbon prices. Ambitious climate policy could result in bioenergy prices of 70 $/GJ (or even 430 $/GJ if bioenergy potential is limited to 100 EJ/year), which indicates a strong demand for bioenergy. For low stabilization scenarios with BECCS availability, we find that the carbon value of biomass tends to exceed its pure energy value. Therefore, the driving factor behind investments into bioenergy conversion capacities for electricity and hydrogen production are the revenues generated from negative emissions, rather than from energy production. However, in REMIND modern bioenergy is predominantly used to produce low-carbon fuels, since the transport sector has significantly fewer low-carbon alternatives to biofuels than the power sector. Since negative emissions increase the amount of permissible emissions from fossil fuels, given a climate target, bioenergy acts as a complement to fossils rather than a substitute. This makes the short-term and long-term deployment of fossil fuels dependent on the long-term availability of BECCS.

Published

2013

19. Assessing uncertainties in land cover projections

Author

Robert Dunford, Tomoko Hasegawa, Katherine Calvin, Jonathan C. Doelman, Adam Butler, Florian Humpenöder, Claudia Baranzelli, Kerstin Engström, Jevgenijs Steinbuks, Filipe Batista e Silva, Timothy M. Lenton, Peter H. Verburg, Almut Arneth, Tamás Krisztin, Reinhard Prestele, Atul K. Jain, Prasanth Meiyappan, Tom Powell, Chris Jacobs-Crisioni, Shinichiro Fujimori, Sascha Holzhauer, Petr Havlik, Carlo Lavalle, Paula A. Harrison, Page Kyle, Peter Alexander, Alexander Popp, Ronald D. Sands, Andrzej Tabeau, Calum Brown, Elke Stehfest, Rüdiger Schaldach, Nicolas Dendoncker, David A. Eitelberg, Jiayi Liu, Mark Rounsevell, Hans van Meijl, Marshall Wise, and Earth and Climate

Subjects

010504 meteorology & atmospheric sciences, Earth, Planet, Climate, Cropland, Land use model, 010501 environmental sciences, 01 natural sciences, land cover, Range (statistics), SDG 13 - Climate Action, International Policy, General Environmental Science, Global and Planetary Change, Ecology, Programmamanagement, Environmental resource management, Uncertainty, Earth, Plants, Biological Sciences, Adaptation strategies, model inter-comparison, Work (electrical), Land cover, Climate Change, Model inter-comparison, Ecology and Environment, Lead (geology), cropland, Environmental Chemistry, SDG 2 - Zero Hunger, Internationaal Beleid, Earth (Planet), 0105 earth and related environmental sciences, Hydrology, Land use, business.industry, land use, 15. Life on land, Earth system science, 13. Climate action, Environmental science, Planet, business, Environmental Sciences, Forecasting

Abstract

Understanding uncertainties in land cover projections is critical to investigating land-based climate mitigation policies, assessing the potential of climate adaptation strategies, and quantifying the impacts of land cover change on the climate system. Here we identify and quantify uncertainties in global and European land cover projections over a diverse range of model types and scenarios, extending the analysis beyond the agro-economic models included in previous comparisons. The results from 75 simulations over 18 models are analysed and show a large range in land cover area projections, with the highest variability occurring in future cropland areas. We demonstrate systematic differences in land cover areas associated with the characteristics of the modelling approach, which is at least as great as the differences attributed to the scenario variations. The results lead us to conclude that a higher degree of uncertainty exists in land use projections than currently included in climate or earth system projections. To account for land use uncertainty, it is recommended to use a diverse set of models and approaches when assessing the potential impacts of land cover change on future climate. Additionally, further work is needed to better understand the assumptions driving land use model results and reveal the causes of uncertainty in more depth, to help reduce model uncertainty and improve the projections of land cover. This article is protected by copyright. All rights reserved.

Published

2016

20. Investigating afforestation and bioenergy CCS as climate change mitigation strategies

Author

Alexander Popp, Benjamin Leon Bodirsky, Miodrag Stevanovic, Isabelle Weindl, Jan Dietrich, David Klein, Florian Humpenöder, Hermann Lotze-Campen, Christoph Müller, and Markus Bonsch

Subjects

Climate change, bioenergy, Carbon sequestration, 577 Ökologie, 7. Clean energy, climate change mitigation, 12. Responsible consumption, land-use modeling, Bioenergy, Environmental protection, afforestation, 11. Sustainability, ddc:333, Afforestation, ddc:577, General Environmental Science, Renewable Energy, Sustainability and the Environment, Agroforestry, Public Health, Environmental and Occupational Health, Carbon capture and storage (timeline), carbon capture and storage, Bio-energy with carbon capture and storage, 15. Life on land, carbon sequestration, land-based mitigation, Climate change mitigation, 13. Climate action, Greenhouse gas, Environmental science

Abstract

The land-use sector can contribute to climate change mitigation not only by reducing greenhouse gas (GHG) emissions, but also by increasing carbon uptake from the atmosphere and thereby creating negative CO2 emissions. In this paper, we investigate two land-based climate change mitigation strategies for carbon removal: (1) afforestation and (2) bioenergy in combination with carbon capture and storage technology (bioenergy CCS). In our approach, a global tax on GHG emissions aimed at ambitious climate change mitigation incentivizes land-based mitigation by penalizing positive and rewarding negative CO2 emissions from the land-use system. We analyze afforestation and bioenergy CCS as standalone and combined mitigation strategies. We find that afforestation is a cost-efficient strategy for carbon removal at relatively low carbon prices, while bioenergy CCS becomes competitive only at higher prices. According to our results, cumulative carbon removal due to afforestation and bioenergy CCS is similar at the end of 21st century (600–700 GtCO2), while land-demand for afforestation is much higher compared to bioenergy CCS. In the combined setting, we identify competition for land, but the impact on the mitigation potential (1000 GtCO2) is partially alleviated by productivity increases in the agricultural sector. Moreover, our results indicate that early-century afforestation presumably will not negatively impact carbon removal due to bioenergy CCS in the second half of the 21st century. A sensitivity analysis shows that land-based mitigation is very sensitive to different levels of GHG taxes. Besides that, the mitigation potential of bioenergy CCS highly depends on the development of future bioenergy yields and the availability of geological carbon storage, while for afforestation projects the length of the crediting period is crucial.

Published

2014

21. Livestock production and the water challenge of future food supply: Implications of agricultural management and dietary choices

Author

Anne Biewald, Sibyll Schaphoff, Hermann Lotze-Campen, Isabelle Weindl, Alexander Popp, Miodrag Stevanovic, Benjamin Leon Bodirsky, Susanne Rolinski, Jan Philipp Dietrich, Florian Humpenöder, and Christoph Müller

Subjects

010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Geography, Planning and Development, 02 engineering and technology, Management, Monitoring, Policy and Law, 01 natural sciences, Water scarcity, Water conservation, Consumptive water use, Environmental protection, Farm water, Agricultural productivity, 0105 earth and related environmental sciences, 2. Zero hunger, Global and Planetary Change, Ecology, business.industry, 15. Life on land, 6. Clean water, 020801 environmental engineering, Water resources, 13. Climate action, Agriculture, Environmental science, Water resource management, business, Water use

Abstract

Human activities use more than half of accessible freshwater, above all for agriculture. Most approaches for reconciling water conservation with feeding a growing population focus on the cropping sector. However, livestock production is pivotal to agricultural resource use, due to its low resource-use efficiency upstream in the food supply chain. Using a global modelling approach, we quantify the current and future contribution of livestock production, under different demand- and supply-side scenarios, to the consumption of “green” precipitation water infiltrated into the soil and “blue” freshwater withdrawn from rivers, lakes and reservoirs. Currently, cropland feed production accounts for 38% of crop water consumption and grazing involves 29% of total agricultural water consumption (9990 km3 yr−1). Our analysis shows that changes in diets and livestock productivity have substantial implications for future consumption of agricultural blue water (19–36% increase compared to current levels) and green water (26–69% increase), but they can, at best, slow down trends of rising water requirements for decades to come. However, moderate productivity reductions in highly intensive livestock systems are possible without aggravating water scarcity. Productivity gains in developing regions decrease total agricultural water consumption, but lead to expansion of irrigated agriculture, due to the shift from grassland/green water to cropland/blue water resources. While the magnitude of the livestock water footprint gives cause for concern, neither dietary choices nor changes in livestock productivity will solve the water challenge of future food supply, unless accompanied by dedicated water protection policies.

22. Peatland protection and restoration are key for climate change mitigation

Author

Jens Leifeld, Florian Humpenöder, Lorenzo Menichetti, Hermann Lotze-Campen, Kristine Karstens, Alexander Popp, and Alexandra Barthelmes

Subjects

Peat, 010504 meteorology & atmospheric sciences, Population, peatland degradation, Context (language use), 010501 environmental sciences, Carbon sequestration, 01 natural sciences, 577 Ökologie, climate change mitigation, mitigation pathway, Environmental protection, ddc:577, education, 0105 earth and related environmental sciences, General Environmental Science, education.field_of_study, Land use, Renewable Energy, Sustainability and the Environment, peatland restoration, Public Health, Environmental and Occupational Health, Carbon sink, 15. Life on land, land-based mitigation, Climate change mitigation, 13. Climate action, Greenhouse gas, large-scale bioenergy, Environmental science, peatland protection

Abstract

Peatlands cover only about 3% the global land area, but store about twice as much carbon as global forest biomass. If intact peatlands are drained for agriculture or other human uses, peat oxidation can result in considerable CO2 emissions and other greenhouse gases (GHG) for decades or even centuries. Despite their importance, emissions from degraded peatlands have so far not been included explicitly in mitigation pathways compatible with the Paris Agreement. Such pathways include land-demanding mitigation options like bioenergy or afforestation with substantial consequences for the land system. Therefore, besides GHG emissions owing to the historic conversion of intact peatlands, the increased demand for land in current mitigation pathways could result in drainage of presently intact peatlands, e.g. for bioenergy production. Here, we present the first quantitative model-based projections of future peatland dynamics and associated GHG emissions in the context of a 2 °C mitigation pathway. Our spatially explicit land-use modelling approach with global coverage simultaneously accounts for future food demand, based on population and income projections, and land-based mitigation measures. Without dedicated peatland policy and even in the case of peatland protection, our results indicate that the land system would remain a net source of CO2 throughout the 21st century. This result is in contrast to the outcome of current mitigation pathways, in which the land system turns into a net carbon sink by 2100. However, our results indicate that it is possible to reconcile land use and GHG emissions in mitigation pathways through a peatland protection and restoration policy. According to our results, the land system would turn into a global net carbon sink by 2100, as projected by current mitigation pathways, if about 60% of present-day degraded peatlands would be rewetted in the coming decades, next to the protection of intact peatlands. DFG Priority Program “Climate Engineering: Risks, Challenges, Opportunities?” (SPP 1689) Horizon 2020 Framework Programmehttp://dx.doi.org/10.13039/100010661