Hostname: page-component-cd9895bd7-hc48f Total loading time: 0 Render date: 2024-12-27T10:46:42.800Z Has data issue: false hasContentIssue false

Climate change challenges require collaborative research to drive agrifood system transformation

Published online by Cambridge University Press:  02 April 2018

Gabrielle E. Roesch-McNally*
Affiliation:
USDA Northwest Climate Hub, 3200 SW Jefferson Ave, Corvallis, OR 97331, USA
Andrea Basche
Affiliation:
University of Nebraska-Lincoln, Plant Sciences hall 279G, Lincoln, NE 68583, USA
Rebecca Schewe
Affiliation:
Maxwell/Syracuse University, 426 Eggers Hall, Syracuse, NY 13244-1020, USA
*
Author for correspondence: Gabrielle E. Roesch-McNally, E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Type
Editorial
Creative Commons
This is a work of the U.S. Government and is not subject to copyright protection in the United States.
Copyright
Copyright © Cambridge University Press 2018

The recent Climate Science Special Report released as part of the Fourth National Climate Assessment confirms that we are living through the warmest period in modern civilization and that human activities are the primary driver of this warming (Wuebbles et al., Reference Wuebbles, Fahey, Hibbard, DeAngelo, Doherty, Hayhoe, Horton, Kossin, Taylor, Waple, Weaver, Wuebbles, Fahey, Hibbard, Dokken, Stewart and Maycock2017). These climatic changes have and will continue to impact global agricultural production, with food security and production consequences that will be felt unequally across the planet. Agricultural activities contribute to global warming emissions, while also offering opportunities for greenhouse gas mitigation. It is clear that the agrifood system will have to adapt to a changing climate. To better assess climate influences on agricultural systems in this themed issue of Renewable Agriculture and Food Systems, we challenged authors to submit interdisciplinary research that examines climate change adaptation and mitigation in agriculture and subsequent interconnected impacts to the food system. Indeed, agrifood systems provide a fertile context for examining climate change from multiple disciplines.

In this issue

Authors in this special issue addressed climate change from a range of agrifood contexts, including the impact of climate change on producer decision-making, vulnerable populations, communities, crop ecology, soil health and food systems policy. Several papers in this themed issue build upon important work exploring agricultural stakeholder views and decision-making relative to climate change. Lane et al. (Reference Lane, Chatrchyan, Tobin, Thorn, Allred and Radhakrishna2018) suggest that skepticism towards anthropogenic climate change among farmers, structural influences such as financial and economic pressures, and broader risk perceptions associated with non-climate concerns limit adaptive and mitigative actions among farmers in New York and Pennsylvania. In Castellano and Moroney's (Reference Castellano and Moroney2018) preliminary research on Idaho farmers, they find that additional factors, including the presence of an heir and location vis a vis the rural–urban interface, might influence farmers’ adaptation strategies. Examining other actors in the agrifood system, Schattman et al. (Reference Schattman, Roesch-McNally, Wiener, Niles and Hollinger2018) conducted a survey of over 4000 U.S. Department of Agriculture Farm Service Agency field staff and outline opportunities to increase employee exposure and proficiency with weather and climate information to meet the needs of American farmers.

It is also critically important to examine climate change in the context of the most vulnerable global populations. To address this need, Reyes et al. (Reference Reyes, Wiener, Doan-Crider and Novak2018) highlight outcomes from a 2017 National Adaptation Forum working group examining how federal partnerships can be strengthened to support tribal agricultural and natural resource management strategies. They argue that working across the thematic areas highlighted by the working group will improve collaboration with Tribes and improve Native food security as well as production opportunities in the face of climate change. Heckelman et al. (Reference Heckelman, Smukler and Wittman2018), using a participatory method of stakeholder engagement, compared the resilience of organic and conventional small-scale rice farmers in the Philippines and found that organic systems improved farmer adaptive capacity but argued that government and non-governmental interventions are needed to reduce vulnerability. Bezner Kerr et al. (Reference Bezner Kerr, Nyantakyi-Frimpong, Dakishoni, Lupafya, Shumba, Luginaah and Snapp2018) examined how Malawian smallholder farmers learn, perceive, share and apply knowledge about a changing climate and found that participatory agroecological approaches supported the development of smallholder farmer adaptation strategies; however, changing the dominant narrative about farming and climate change remained a greater challenge.

The interdisciplinary study of climate change and agrifood systems requires novel methodological approaches. Osterhoudt (Reference Osterhoudt2018), in her commentary piece, investigated the role of oral histories in a specific agrarian community in Madagascar that suffered a devastating cyclone in 2011, noting that such histories can promote climate adaptation through shared stories and memories of severe events which are expected to become more common due to climate change. Franzen (Reference Franzen2017) demonstrates the importance of using ethnographic film as a methodology that can complement existing cultural research on climate change perceptions and knowledge processes.

This themed issue also examines agriculture and climate change using biophysical data to answer crucial questions about changes across the agrifood system. McGranahan and Polling (Reference McGranahan and Polling2018) used an ecological approach to evaluate how physiologically diverse field crops perform under drought conditions and rising atmospheric carbon dioxide levels. Contrary to other work that has not found strong impacts of near-term carbon dioxide increases, they conclude that atmospheric CO2 of < 575-ppm had significant negative effects on plant physiological responses associated with crop yields. DeLonge and Basche (Reference DeLonge and Basche2017) conducted a global meta-analysis of 37 rangeland experiments and found that improved grazing practices such as increasing complexity and reduced stocking rates significantly increased water infiltration rates, which may offset the impacts of rainfall variability as a result of climate change.

While field trials can reveal differences in climate responses that result from various best management practices, identifying such patterns at a larger scale could help answer questions about regional resilience. Alvarez-Berrios et al. (Reference Alvarez-Berrios, Soto-Bayo, Holupchinski, Fain and Gould2018) paired data on drought mitigation conservation practices and drought frequency across the island of Puerto Rico from 2000 to 2016. They found that the most drought-prone regions did not often overlap with the greatest prevalence of drought mitigation management, highlighting a need for increasing the accessibility of programs that support conservation practice adoption.

Recognizing the importance of addressing the role of policy on climate change, Jordan et al. (Reference Jordan, Mulla, Slotterback, Runck and Hays2017) described models from the Upper Midwest where preliminary programs aim to support a thriving bioeconomy alongside positive environmental outcomes. The authors propose that if programs are properly designed and coordinated on farm and watershed scales, production of diverse bioproducts can efficiently enhance farm profit, bioproducts and water-related services relevant to increased rainfall variability in that region. Further addressing the need for system-wide analyses, Niles et al. (Reference Niles, Ahuja, Barker, Esquivel, Gutterman, Heller, Mango, Porter, Raimond, Tirado and Vermeulen2018) argued that utilizing a food systems framework to assess climate change and its related impacts and opportunities are critical to address the needs of and threats to a global food system in the 21st century.

A call for transformative climate and agrifood systems research

There is still far to go to achieve the vision of truly transdisciplinary and multi-scalar climate change research. Combining social and biophysical data requires researchers to move beyond disciplinary silos to create collaborative research teams and datasets. Transdisciplinary researchers must create shared theoretical frames and build foundations of mutual respect across disciplinary boundaries, including practitioners and diverse research methodology. They must also address pragmatic concerns of combining data that spans a variety of methods, measurements and scales. We applaud the authors in this themed issue who have faced these challenges and offered pioneering work on climate change and the agrifood system. We hope that there will continue to be space for climate change research that works across social and natural science disciplinary boundaries and multiple scalar levels to address the real challenges of climate change.

References

Alvarez-Berrios, NL, Soto-Bayo, S, Holupchinski, E, Fain, SJ and Gould, WA (2018) Correlating drought conservation practices and drought vulnerability in a tropical agricultural system. Renewable Agriculture and Food Systems 33, 279291.Google Scholar
Bezner Kerr, R, Nyantakyi-Frimpong, H, Dakishoni, L, Lupafya, E, Shumba, L, Luginaah, I and Snapp, SS (2018) Knowledge politics in participatory climate change adaptation research on agroecology in Malawi. Renewable Agriculture and Food Systems 33, 238251.Google Scholar
Castellano, RS and Moroney, JL (2018) Farming adaptations in the face of climate change. Renewable Agriculture and Food Systems 33, 206211.Google Scholar
DeLonge, M and Basche, A (2017) Managing grazing lands to improve soils and promote climate change adaptation and mitigation: a global synthesis. Renewable Agriculture and Food Systems 33, 267278.Google Scholar
Franzen, S (2017) Framing nature: visual representations of ecological paradigms. Renewable Agriculture and Food Systems 33, 256258.Google Scholar
Heckelman, A, Smukler, S and Wittman, H (2018) Cultivating climate resilience: a participatory assessment of organic and conventional rice systems in the Philippines. Renewable Agriculture and Food Systems 33, 225237.Google Scholar
Jordan, N, Mulla, D, Slotterback, C, Runck, B and Hays, C (2017) Multifunctional agricultural watersheds for climate adaptation in Midwest USA: commentary. Renewable Agriculture and Food Systems 33, 292296.CrossRefGoogle Scholar
Lane, D, Chatrchyan, A, Tobin, D, Thorn, K, Allred, S and Radhakrishna, R (2018) Climate change and agriculture in New York and Pennsylvania: risk perceptions, vulnerability and adaptation among farmers. Renewable Agriculture and Food Systems 33, 197205.Google Scholar
McGranahan, DA and Polling, BN (2018) Trait-based responses of seven annual crops to elevated CO2 and water limitation. Renewable Agriculture and Food Systems 33, 259266.Google Scholar
Niles, M, Ahuja, R, Barker, T, Esquivel, J, Gutterman, S, Heller, MC, Mango, N, Porter, D, Raimond, R, Tirado, C and Vermeulen, S (2018) Climate change mitigation beyond agriculture: a review of food system opportunities and implications. Renewable Agriculture and Food Systems 33, 297308.Google Scholar
Osterhoudt, S (2018) Remembered resilience: oral history narratives and community resilience in agroforestry systems. Renewable Agriculture and Food Systems 33, 252255.Google Scholar
Reyes, J, Wiener, J, Doan-Crider, D and Novak, R (2018). Building collaborative capacity: Supporting tribal agriculture and natural resources in a changing climate. Renewable Agriculture and Food Systems 33, 222224.Google Scholar
Schattman, RE, Roesch-McNally, GE, Wiener, S, Niles, MT and Hollinger, DY (2018) Farm service agency employee intentions to use weather and climate data in professional services. Renewable Agriculture and Food Systems 33, 212221.Google Scholar
Wuebbles, DJ, Fahey, DW, Hibbard, KA, DeAngelo, B, Doherty, S, Hayhoe, K, Horton, R, Kossin, JP, Taylor, PC, Waple, AM and Weaver, CP (2017) Executive summary. In Wuebbles, DJ, Fahey, DW, Hibbard, KA, Dokken, DJ, Stewart, BC and Maycock, TK (eds). Climate Science Special Report: Fourth National Climate Assessment, vol. I. Washington, DC: U.S. Global Change Research Program, pp. 1234. doi: 10.7930/J0DJ5CTG.Google Scholar