Your search keyword '"Seufert V"' showing total 21 results

1. Creating leadership collectives for sustainability transformations

Author

Care, O., Bernstein, M. J., Chapman, M., Diaz Reviriego, I., Dressler, G., Felipe-Lucia, M. R., Friis, C., Graham, S., Hänke, H., Haider, L. J., Hernández-Morcillo, M., Hoffmann, H., Kernecker, M., Nicol, P., Piñeiro, C., Pitt, H., Schill, C., Seufert, V., Shu, K., Valencia, V., and Zaehringer, J. G.

Published

2021

2. From functional diversity to human well-being: A conceptual framework for agroecosystem sustainability

Author

de la Riva, E.G., Ulrich, W., Batáry, P., Baudry, J., Beaumelle, L., Bucher, R., Čerevková, A., Felipe-Lucia, Maria, Gallé, R., Kesse-Guyot, E., Rembiałkowska, E., Rusch, A., Seufert, V., Stanley, D., Birkhofer, K., de la Riva, E.G., Ulrich, W., Batáry, P., Baudry, J., Beaumelle, L., Bucher, R., Čerevková, A., Felipe-Lucia, Maria, Gallé, R., Kesse-Guyot, E., Rembiałkowska, E., Rusch, A., Seufert, V., Stanley, D., and Birkhofer, K.

Abstract

CONTEXTAgricultural intensification contributes to global food security and well-being by supplying the food demand of a growing human population. However, ongoing land-use change and intensification seriously affect the abundance, diversity and distribution of species, besides many other impacts, thereby threatening the functioning of ecosystems worldwide. Despite the accumulating evidence that the current agricultural model is unsustainable, we are far from understanding the consequences of functional diversity loss for functioning and ecosystem service supply and the potential long-term threats to food security and human well-being.OBJECTIVEIn this review, we propose a conceptual framework to understand the relationships between functional diversity and human well-being that also considers agroecosystem health. To this end, we identify the most commonly assumed relationships linking functional diversity to regulating and provisioning agroecosystem services and their importance for human well-being, emphasising the most serious knowledge gaps in the individual pathways of the conceptual framework.METHODSA consortium formed by an international panel of experts from different disciplines including functional diversity, ecosystem services and human health compiled 275 articles. Members of the consortium proposed literature to exemplify each specific aspect of the conceptual framework in the text, in accordance with his/her field of expertise. The guideline for all experts was to focus mostly in current literature (38% of the references are from the last 5 years and 66% from the last decade), with special interest in reviews and synthesis articles (42% of the references), as well as meta-analyses and global studies (10% of the references).RESULTS AND CONCLUSIONSThe factors that influence agroecosystem health are extremely complex, involving both services and disservices related to land-use management and environmental conditions. The global human population n

Published

2023

3. Ten facts about land systems for sustainability

Author

Meyfroidt, P., de Bremond, A., Ryan, C. M., Aspinall, R., Archer, E., Chhabra, A., Camara, G., Corbera, E., DeFries, R., Díaz, S., Dong, J., Ellis, E. C., Erb, K. H., Fisher, J. A., Garrett, R. D., Golubiewski, N. E., Grau, H. R., Haberl, H., Grove, J. M., Heinimann, A., Hostert, P., Jobbágy, E. G., Kerr, S., Kuemmerle, T., Lambin, E. F., Lavorel, S., Lele, S., Mertz, O., Messerli, P., Metternicht, G., Munroe, D. K., Nagendra, H., Nielsen, J. Ø, Ojima, D. S., Parker, D. C., Pascual, U., Porter, J. R., Ramankutty, N., Reenberg, A., Chowdhury, R. R., Seto, K. C., Seufert, V., Shibata, H., Thomson, A., Turner, B. L., Veldkamp, T., Urabe, J., Verburg, P. H., Zeleke, G., zu Ermgassen, E. K. H. J., Meyfroidt, P., de Bremond, A., Ryan, C. M., Aspinall, R., Archer, E., Chhabra, A., Camara, G., Corbera, E., DeFries, R., Díaz, S., Dong, J., Ellis, E. C., Erb, K. H., Fisher, J. A., Garrett, R. D., Golubiewski, N. E., Grau, H. R., Haberl, H., Grove, J. M., Heinimann, A., Hostert, P., Jobbágy, E. G., Kerr, S., Kuemmerle, T., Lambin, E. F., Lavorel, S., Lele, S., Mertz, O., Messerli, P., Metternicht, G., Munroe, D. K., Nagendra, H., Nielsen, J. Ø, Ojima, D. S., Parker, D. C., Pascual, U., Porter, J. R., Ramankutty, N., Reenberg, A., Chowdhury, R. R., Seto, K. C., Seufert, V., Shibata, H., Thomson, A., Turner, B. L., Veldkamp, T., Urabe, J., Verburg, P. H., Zeleke, G., and zu Ermgassen, E. K. H. J.

Published

2022

4. Creating leadership collectives for sustainability transformations

Author

Care, O; https://orcid.org/0000-0002-0595-7413, Bernstein, M J, Chapman, Mollie; https://orcid.org/0000-0003-1399-2144, Diaz Reviriego, I, Dressler, G, Felipe-Lucia, M R, Friis, C, Graham, S, Hänke, H, Haider, L J, Hernández-Morcillo, M, Hoffmann, H, Kernecker, M, Nicol, P, Piñeiro, C, Pitt, H, Schill, C, Seufert, V, Shu, K, Valencia, V, Zaehringer, J G, Care, O; https://orcid.org/0000-0002-0595-7413, Bernstein, M J, Chapman, Mollie; https://orcid.org/0000-0003-1399-2144, Diaz Reviriego, I, Dressler, G, Felipe-Lucia, M R, Friis, C, Graham, S, Hänke, H, Haider, L J, Hernández-Morcillo, M, Hoffmann, H, Kernecker, M, Nicol, P, Piñeiro, C, Pitt, H, Schill, C, Seufert, V, Shu, K, Valencia, V, and Zaehringer, J G

Abstract

Enduring sustainability challenges requires a new model of collective leadership that embraces critical reflection, inclusivity and care. Leadership collectives can support a move in academia from metrics to merits, from a focus on career to care, and enact a shift from disciplinary to inter- and trans-disciplinary research. Academic organisations need to reorient their training programs, work ethics and reward systems to encourage collective excellence and to allow space for future leaders to develop and enact a radically re-imagined vision of how to lead as a collective with care for people and the planet.

Published

2021

5. Positive but variable effects of crop diversification on biodiversity and ecosystem services

Author

Beillouin, D., primary, Ben-Ari, T., additional, Malézieux, E., additional, Seufert, V., additional, and Makowski, D., additional

Published

2020

6. Current and Potential Contributions of Organic Agriculture to Diversification of the Food Production System

Author

Seufert, V., Mehrabi, Zia, Gabriel, Doreen, Benton, Tim G., Lemaire, Gilles, De Faccio Carvalho, Paulo Cesar, Kronberg, Scott, Recous, Sylvie, Environmental Geography, Lemaire, Gilles, De Faccio Carvalho, Paulo Cesar, Kronberg, Scott, and Recous, Sylvie

Subjects

Agroecosystem, Natural resource economics, business.industry, Agriculture, Organic farming, Food processing, Food systems, Climate change, Livestock, Business, Diversification (marketing strategy), SDG 2 - Zero Hunger

Abstract

Organic agriculture is a system that aims to primarily use ecologic processes rather than external inputs to manage crops and livestock. Diversity is a key component of natural ecosystems and organic agriculture often includes the use of diversity as a management paradigm, as well as the stated goal to enhance diversity. But how does organic agriculture contribute to diversification in practice? And what are the potentials and limits of organic agriculture to enhance the diversity of the food production system? In this chapter, we will examine the evidence for implementation of diversification practices by organic farmers, as well for the diversification outcomes of organic agriculture. We will then conclude with a discussion and outlook on how organic agriculture can enhance the diversification of agroecosystems and the food system in general. On the one hand, large-scale economic drivers today typically favor the homogenization of food production systems, and organic agriculture—being a production system that is embedded in the existing food system—is thus faced with limits in its ability to foster diversification at the system level. On the other hand, multiple drivers, including climate change but also the increased importance of consumers in the food system, may alter the dominant socioeconomic drivers and may favor more resilient organic or organic-like production systems in the future. Organic agriculture may thus provide important contributions for a trajectory for moving toward more diversified food production, not only through diversification occurring within organic systems, but also by providing important lessons on diversified agricultural systems for conventional agriculture.

Published

2019

7. New training to meet the global phosphorus challenge

Author

Reitzel, K, Bennett, WW, Berger, N, Brownlie, WJ, Bruun, S, Christensen, ML, Cordell, D, Van Dijk, K, Egemose, S, Eigner, H, Glud, RN, Grönfors, O, Hermann, L, Houot, S, Hupfer, M, Jacobs, B, Korving, L, Kjærgaard, C, Liimatainen, H, Van Loosdrecht, MCM, Macintosh, KA, Magid, J, Maia, F, Martin-Ortega, J, McGrath, J, Meulepas, R, Murry, M, Neset, TS, Neumann, G, Nielsen, UG, Nielsen, PH, O'Flaherty, V, Qu, H, Santner, J, Seufert, V, Spears, B, Stringer, LC, Stutter, M, Verburg, PH, Wilfert, P, Williams, PN, Metson, GS, Reitzel, K, Bennett, WW, Berger, N, Brownlie, WJ, Bruun, S, Christensen, ML, Cordell, D, Van Dijk, K, Egemose, S, Eigner, H, Glud, RN, Grönfors, O, Hermann, L, Houot, S, Hupfer, M, Jacobs, B, Korving, L, Kjærgaard, C, Liimatainen, H, Van Loosdrecht, MCM, Macintosh, KA, Magid, J, Maia, F, Martin-Ortega, J, McGrath, J, Meulepas, R, Murry, M, Neset, TS, Neumann, G, Nielsen, UG, Nielsen, PH, O'Flaherty, V, Qu, H, Santner, J, Seufert, V, Spears, B, Stringer, LC, Stutter, M, Verburg, PH, Wilfert, P, Williams, PN, and Metson, GS

Published

2019

8. Land management: data availability and process understanding for global change studies

Author

Erb, K.H., Luyssaert, S., Meyfroidt, P., Pongratz, J., Don, A., Kloster, S., Kuemmerle, T., Fetzel, T., Fuchs, R., Herold, M., Haberl, H., Jones, C.D., Marín-Spoiotta, E., McCallum, I., Robertson, E., Seufert, V., Fritz, S., Valade, A., Wiltshire, A., Dolman, A.J., Erb, K.H., Luyssaert, S., Meyfroidt, P., Pongratz, J., Don, A., Kloster, S., Kuemmerle, T., Fetzel, T., Fuchs, R., Herold, M., Haberl, H., Jones, C.D., Marín-Spoiotta, E., McCallum, I., Robertson, E., Seufert, V., Fritz, S., Valade, A., Wiltshire, A., and Dolman, A.J.

Abstract

In the light of daunting global sustainability challenges such as climate change, biodiversity loss and food security, improving our understanding of the complex dynamics of the Earth system is crucial. However, large knowledge gaps related to the effects of land management persist, in particular those human-induced changes in terrestrial ecosystems that do not result in land-cover conversions. Here, we review the current state of knowledge of ten common land management activities for their biogeochemical and biophysical impacts, the level of process understanding and data availability. Our review shows that ca. one-tenth of the ice-free land surface is under intense human management, half under medium and one-fifth under extensive management. Based on our review, we cluster these ten management activities into three groups: (i) management activities for which data sets are available, and for which a good knowledge base exists (cropland harvest and irrigation); (ii) management activities for which sufficient knowledge on biogeochemical and biophysical effects exists but robust global data sets are lacking (forest harvest, tree species selection, grazing and mowing harvest, N fertilization); and (iii) land management practices with severe data gaps concomitant with an unsatisfactory level of process understanding (crop species selection, artificial wetland drainage, tillage and fire management and crop residue management, an element of crop harvest). Although we identify multiple impediments to progress, we conclude that the current status of process understanding and data availability is sufficient to advance with incorporating management in, for example, Earth system or dynamic vegetation models in order to provide a systematic assessment of their role in the Earth system. This review contributes to a strategic prioritization of research efforts across multiple disciplines, including land system research, ecological research and Earth system modelling.

Published

2017

9. Land management: data availability and process understanding for global change studies

Author

Erb, K-H., Luyssaert, S., Meyfroidt, P., Pongratz, J., Don, A., Kloster, S., Kuemmerle, T., Fetzel, T., Fuchs, R., Herold, M., Haberl, H., Jones, C. D., Marín Spiotta, E., McCallum, I., Robertson, E., Seufert, V., Fritz, S., Valade, A., Wiltshire, A., Dolman, A.J., Erb, K-H., Luyssaert, S., Meyfroidt, P., Pongratz, J., Don, A., Kloster, S., Kuemmerle, T., Fetzel, T., Fuchs, R., Herold, M., Haberl, H., Jones, C. D., Marín Spiotta, E., McCallum, I., Robertson, E., Seufert, V., Fritz, S., Valade, A., Wiltshire, A., and Dolman, A.J.

Abstract

In light of daunting global sustainability challenges such as climate change, biodiversity loss and food security, improving our understanding of the complex dynamics of the Earth system is crucial. However, large knowledge gaps related to the effects of land management persist, in particular those human-induced changes in terrestrial ecosystems that do not result in land cover conversions. Here we review the current state of knowledge of ten common land management activities for their biogeochemical and biophysical impacts, the level of process-understanding and data availability. Our review shows that ca. one tenth of the ice free land surface is under intense human management, half under medium and one fifth under extensive management. Based on our review, we cluster these ten management activities into three groups: (1) management activities for which datasets are available, and for which a good knowledge base exists (cropland harvest and irrigation); (2) management activities for which sufficient knowledge on biogeochemical and biophysical effects exists but robust global datasets are lacking (forest harvest, tree species selection, grazing and mowing harvest, N-fertilization); and (3) land management practices with severe data gaps concomitant with an unsatisfactory level of process understanding (crop species selection, artificial wetland drainage, tillage and fire management and crop residue management, an element of crop harvest). Although we identify multiple impediments to progress, we conclude that the current status of process understanding and data availability is sufficient to advance with incorporating management in e.g. Earth System or Dynamic Vegetation models in order to provide a systematic assessment of their role in the Earth system. This review contributes to a strategic prioritization of research efforts across multiple disciplines, including land system research, ecological research and Earth system modelling.

Published

2017

10. Urban agriculture: a global analysis of the space constraint to meet urban vegetable demand

Author

Martellozzo, F, primary, Landry, J-S, additional, Plouffe, D, additional, Seufert, V, additional, Rowhani, P, additional, and Ramankutty, N, additional

Published

2014

11. Reaping what we sow: Centering values in food systems transformations research.

Author

Care O, Zaehringer JG, Bernstein MJ, Chapman M, Friis C, Graham S, Haider LJ, Hernández-Morcillo M, Hoffmann H, Kernecker ML, Pitt H, and Seufert V

Abstract

In many transdisciplinary research settings, a lack of attention to the values underpinning project aims can inhibit stakeholder engagement and ultimately slow or undermine project outcomes. As a research collective (The Careoperative), we have developed a set of four shared values through a facilitated visioning process, as central to the way we work together: care, reflexivity, inclusivity, and collectivity. In this paper, we explore the implications of a values-centered approach to collaboration in food system transformation research. The paper presents two cases that illustrate how researchers might approach centering values in practice. Where much research on food system transformation focuses on values of food system stakeholders, we contribute insights into the values of researchers in such transdisciplinary endeavors. Specifically, we argue that researchers working on sustainability transformations need to be better prepared to engage in such reflections and aspire to embody values aligned with the transformations they seek to research., (© 2024. The Author(s).)

Published

2024

12. Successful implementation of global targets to reduce nutrient and pesticide pollution requires suitable indicators.

Author

Möhring N, Kanter D, Aziz T, Castro IB, Maggi F, Schulte-Uebbing L, Seufert V, Tang FHM, Zhang X, and Leadley P

Subjects

Agriculture, Environmental Monitoring, Nutrients, Pesticides analysis

Published

2023

13. Ten facts about land systems for sustainability.

Author

Meyfroidt P, de Bremond A, Ryan CM, Archer E, Aspinall R, Chhabra A, Camara G, Corbera E, DeFries R, Díaz S, Dong J, Ellis EC, Erb KH, Fisher JA, Garrett RD, Golubiewski NE, Grau HR, Grove JM, Haberl H, Heinimann A, Hostert P, Jobbágy EG, Kerr S, Kuemmerle T, Lambin EF, Lavorel S, Lele S, Mertz O, Messerli P, Metternicht G, Munroe DK, Nagendra H, Nielsen JØ, Ojima DS, Parker DC, Pascual U, Porter JR, Ramankutty N, Reenberg A, Roy Chowdhury R, Seto KC, Seufert V, Shibata H, Thomson A, Turner BL 2nd, Urabe J, Veldkamp T, Verburg PH, Zeleke G, and Zu Ermgassen EKHJ

Subjects

Ecosystem, Humans, Renewable Energy, Social Change, Agriculture, Conservation of Natural Resources methods

Abstract

Land use is central to addressing sustainability issues, including biodiversity conservation, climate change, food security, poverty alleviation, and sustainable energy. In this paper, we synthesize knowledge accumulated in land system science, the integrated study of terrestrial social-ecological systems, into 10 hard truths that have strong, general, empirical support. These facts help to explain the challenges of achieving sustainability in land use and thus also point toward solutions. The 10 facts are as follows: 1) Meanings and values of land are socially constructed and contested; 2) land systems exhibit complex behaviors with abrupt, hard-to-predict changes; 3) irreversible changes and path dependence are common features of land systems; 4) some land uses have a small footprint but very large impacts; 5) drivers and impacts of land-use change are globally interconnected and spill over to distant locations; 6) humanity lives on a used planet where all land provides benefits to societies; 7) land-use change usually entails trade-offs between different benefits-"win-wins" are thus rare; 8) land tenure and land-use claims are often unclear, overlapping, and contested; 9) the benefits and burdens from land are unequally distributed; and 10) land users have multiple, sometimes conflicting, ideas of what social and environmental justice entails. The facts have implications for governance, but do not provide fixed answers. Instead they constitute a set of core principles which can guide scientists, policy makers, and practitioners toward meeting sustainability challenges in land use., Competing Interests: The authors declare no competing interest., (Copyright © 2022 the Author(s). Published by PNAS.)

Published

2022

14. Positive but variable effects of crop diversification on biodiversity and ecosystem services.

Author

Beillouin D, Ben-Ari T, Malézieux E, Seufert V, and Makowski D

Subjects

Animals, Biodiversity, Crops, Agricultural, Soil, Agriculture, Ecosystem

Abstract

Ecological theory suggests that biodiversity has a positive and stabilizing effect on the delivery of ecosystem services. Yet, the impacts of increasing the diversity of cultivated crop species or varieties in agroecosystems are still under scrutiny. The available empirical evidence is scattered in scope, agronomic and geographic contexts, and impacts on ecosystem services may depend on the type of diversification strategy used. To robustly assess the effects of crop diversification in agroecosystems, we compiled the results of 95 meta-analyses integrating 5156 experiments conducted over 84 experimental years and representing more than 54,500 paired observations on 120 crop species in 85 countries. Overall, our synthesis of experimental data from across the globe shows that crop diversification enhances not only crop production (median effect +14%) but also the associated biodiversity (+24%, i.e., the biodiversity of non-cultivated plants and animals), and several supporting and regulating ecosystem services including water quality (+51%), pest and disease control (+63%) and soil quality (+11%). However, there was substantial variability in the results for each individual ecosystem service between different diversification strategies such as agroforestry, intercropping, cover crops, crop rotation or variety mixtures. Agroforestry is particularly effective in delivering multiple ecosystem services, that is, water regulation and quality, pest and diseases regulation, associated biodiversity, long-term soil productivity and quality. Variety mixtures, instead, provide the lowest benefits, whereas the other strategies show intermediate results. Our results highlight that while increasing the diversity of cultivated crop species or varieties in agroecosystems represents a very promising strategy for more sustainable land management, contributing to enhanced yields, enhanced biodiversity and ecosystem services, some crop diversification strategies are more effective than others in supporting key ecosystem services., (© 2021 John Wiley & Sons Ltd.)

Published

2021

15. Global option space for organic agriculture is delimited by nitrogen availability.

Author

Barbieri P, Pellerin S, Seufert V, Smith L, Ramankutty N, and Nesme T

Abstract

Organic agriculture is widely accepted as a strategy to reduce the environmental impacts of food production and help achieve global climate and biodiversity targets. However, studies concluding that organic farming could satisfy global food demand have overlooked the key role that nitrogen plays in sustaining crop yields. Using a spatially explicit biophysical optimization model that accounts for crop growth nitrogen requirements, we show that, in the absence of synthetic nitrogen fertilizers, the production gap between organic and conventional agriculture increases as organic agriculture expands globally (with organic producing 36% less food for human consumption than conventional in a fully organic world). Yet, by targeting both food supply (via a redesign of the livestock sector) and demand (by reducing average per capita caloric intake), public policies could support a transition towards organic agriculture in 40-60% of the global agricultural area even under current nitrogen limitations thus helping to achieve important environmental and health benefits., (© 2021. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2021

16. A meta-analysis of crop response patterns to nitrogen limitation for improved model representation.

Author

Seufert V, Granath G, and Müller C

Subjects

Carbon metabolism, Carbon Dioxide metabolism, Photosynthesis, Plant Leaves metabolism, Rhizosphere, Crops, Agricultural physiology, Models, Biological, Nitrogen metabolism, Plant Development

Abstract

The representation of carbon-nitrogen (N) interactions in global models of the natural or managed land surface remains an important knowledge gap. To improve global process-based models we require a better understanding of how N limitation affects photosynthesis and plant growth. Here we present the findings of a meta-analysis to quantitatively assess the impact of N limitation on source (photosynthate production) versus sink (photosynthate use) activity, based on 77 highly controlled experimental N availability studies on 11 crop species. Using meta-regressions, we find that it can be insufficient to represent N limitation in models merely as inhibiting carbon assimilation, because in crops complete N limitation more strongly influences leaf area expansion (-50%) than photosynthesis (-34%), while leaf starch is accumulating (+83%). Our analysis thus offers support for the hypothesis of sink limitation of photosynthesis and encourages the exploration of more sink-driven crop modelling approaches. We also show that leaf N concentration changes with N availability and that the allocation of N to Rubisco is reduced more strongly compared to other photosynthetic proteins at low N availability. Furthermore, our results suggest that different crop species show generally similar response patterns to N limitation, with the exception of leguminous crops, which respond differently. Our meta-analysis offers lessons for the improved depiction of N limitation in global terrestrial ecosystem models, as well as highlights knowledge gaps that need to be filled by future experimental studies on crop N limitation response., Competing Interests: The authors have declared that no competing interests exist.

Published

2019

17. New Training to Meet the Global Phosphorus Challenge.

Author

Reitzel K, Bennett WW, Berger N, Brownlie WJ, Bruun S, Christensen ML, Cordell D, van Dijk K, Egemose S, Eigner H, Glud RN, Grönfors O, Hermann L, Houot S, Hupfer M, Jacobs B, Korving L, Kjærgaard C, Liimatainen H, Van Loosdrecht MCM, Macintosh KA, Magid J, Maia F, Martin-Ortega J, McGrath J, Meulepas R, Murry M, Neset TS, Neumann G, Nielsen UG, Nielsen PH, O'Flaherty V, Qu H, Santner J, Seufert V, Spears B, Stringer LC, Stutter M, Verburg PH, Wilfert P, Williams PN, and Metson GS

Subjects

Conservation of Natural Resources, Fertilizers, Phosphorus

Published

2019

18. The Conventional Versus Alternative Agricultural Divide: A Response to Garibaldi et al.

Author

Mehrabi Z, Seufert V, and Ramankutty N

Subjects

Crops, Agricultural, Humans, Agriculture, Conservation of Natural Resources

Published

2017

19. Many shades of gray-The context-dependent performance of organic agriculture.

Author

Seufert V and Ramankutty N

Abstract

Organic agriculture is often proposed as a more sustainable alternative to current conventional agriculture. We assess the current understanding of the costs and benefits of organic agriculture across multiple production, environmental, producer, and consumer dimensions. Organic agriculture shows many potential benefits (including higher biodiversity and improved soil and water quality per unit area, enhanced profitability, and higher nutritional value) as well as many potential costs including lower yields and higher consumer prices. However, numerous important dimensions have high uncertainty, particularly the environmental performance when controlling for lower organic yields, but also yield stability, soil erosion, water use, and labor conditions. We identify conditions that influence the relative performance of organic systems, highlighting areas for increased research and policy support.

Published

2017

20. Land management: data availability and process understanding for global change studies.

Author

Erb KH, Luyssaert S, Meyfroidt P, Pongratz J, Don A, Kloster S, Kuemmerle T, Fetzel T, Fuchs R, Herold M, Haberl H, Jones CD, Marín-Spiotta E, McCallum I, Robertson E, Seufert V, Fritz S, Valade A, Wiltshire A, and Dolman AJ

Subjects

Biodiversity, Ecosystem, Trees, Climate Change, Conservation of Natural Resources

Abstract

In the light of daunting global sustainability challenges such as climate change, biodiversity loss and food security, improving our understanding of the complex dynamics of the Earth system is crucial. However, large knowledge gaps related to the effects of land management persist, in particular those human-induced changes in terrestrial ecosystems that do not result in land-cover conversions. Here, we review the current state of knowledge of ten common land management activities for their biogeochemical and biophysical impacts, the level of process understanding and data availability. Our review shows that ca. one-tenth of the ice-free land surface is under intense human management, half under medium and one-fifth under extensive management. Based on our review, we cluster these ten management activities into three groups: (i) management activities for which data sets are available, and for which a good knowledge base exists (cropland harvest and irrigation); (ii) management activities for which sufficient knowledge on biogeochemical and biophysical effects exists but robust global data sets are lacking (forest harvest, tree species selection, grazing and mowing harvest, N fertilization); and (iii) land management practices with severe data gaps concomitant with an unsatisfactory level of process understanding (crop species selection, artificial wetland drainage, tillage and fire management and crop residue management, an element of crop harvest). Although we identify multiple impediments to progress, we conclude that the current status of process understanding and data availability is sufficient to advance with incorporating management in, for example, Earth system or dynamic vegetation models in order to provide a systematic assessment of their role in the Earth system. This review contributes to a strategic prioritization of research efforts across multiple disciplines, including land system research, ecological research and Earth system modelling., (© 2016 John Wiley & Sons Ltd.)

Published

2017

21. Comparing the yields of organic and conventional agriculture.

Author

Seufert V, Ramankutty N, and Foley JA

Subjects

Agricultural Irrigation, Animals, Crops, Agricultural classification, Crops, Agricultural growth & development, Developed Countries, Developing Countries, Ecology, Ecosystem, Food, Organic supply & distribution, Forestry, Humans, Hydrogen-Ion Concentration, Population Growth, Soil analysis, Soil chemistry, Time Factors, Agriculture methods, Biomass, Conservation of Natural Resources methods, Food Supply statistics & numerical data, Organic Agriculture methods

Abstract

Numerous reports have emphasized the need for major changes in the global food system: agriculture must meet the twin challenge of feeding a growing population, with rising demand for meat and high-calorie diets, while simultaneously minimizing its global environmental impacts. Organic farming—a system aimed at producing food with minimal harm to ecosystems, animals or humans—is often proposed as a solution. However, critics argue that organic agriculture may have lower yields and would therefore need more land to produce the same amount of food as conventional farms, resulting in more widespread deforestation and biodiversity loss, and thus undermining the environmental benefits of organic practices. Here we use a comprehensive meta-analysis to examine the relative yield performance of organic and conventional farming systems globally. Our analysis of available data shows that, overall, organic yields are typically lower than conventional yields. But these yield differences are highly contextual, depending on system and site characteristics, and range from 5% lower organic yields (rain-fed legumes and perennials on weak-acidic to weak-alkaline soils), 13% lower yields (when best organic practices are used), to 34% lower yields (when the conventional and organic systems are most comparable). Under certain conditions—that is, with good management practices, particular crop types and growing conditions—organic systems can thus nearly match conventional yields, whereas under others it at present cannot. To establish organic agriculture as an important tool in sustainable food production, the factors limiting organic yields need to be more fully understood, alongside assessments of the many social, environmental and economic benefits of organic farming systems.

Published

2012