Abstract
This chapter reviews evidence of the impacts of agroecological farming practices on climate adaptation and mitigation. Farm diversification has the strongest evidence for its impacts on climate change adaptation. The evidence for agroecology’s impact on mitigation in LMICs is modest and emphasises carbon sequestration in soil and biomass. Agroforestry has the strongest body of evidence for impacts on mitigation. Locally relevant solutions produced through participatory processes and the co-creation of knowledge with farmers has improved climate change adaptation and mitigation. Knowledge gaps were found in regard to agricultural climate change mitigation, resilience to extreme weather, and agroecology approaches involving livestock, landscape redesign and multi-scalar analysis. There is a need to assess the performance of agricultural development using an outcome-based approach based on agroecological principles and climate change adaptation and mitigation indicators in order to guide donor and national investment. Moreover, direct investment and the scaling of practices for which the current evidence is strongest are needed. These include: (1) agricultural diversification, agroforestry and local adaptation; (2) increase action around resilience to extreme weather and climate change mitigation outcomes in LMICs and build the capacity of policymakers, scientists and institutions from the global South to work on these issues; and (3) compare the cost-effectiveness and outcomes of agroecology approaches with other agricultural development interventions at multiple scales, including the valuation of environmental and social benefits to better evaluate alternative approaches to sustainable agriculture.
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1 Introduction
1.1 Does Agroecology Lead to Better Climate Change Outcomes?
Food systems need to meet food security, nutrition and environmental goals, especially in a world with growing demand and a changing climate. There is now broad consensus on the need to transform current food systems towards more sustainable models. Agroecology is increasingly seen as a framework for transforming food systems (HLPE 2019). A key question is: how far can agroecology meet the needs for climate change adaptation and mitigation in food systems, especially in low- and middle-income countries (LMICs) and at large scales?
To address this question, we conducted a rapid, evidence-based review to assess the quality and strength of evidence regarding (i) the impact of agroecological approaches on climate change mitigation and adaptation in LMICs, and (ii) the programming approaches and conditions supporting large-scale transitions to agroecology.
Defining agroecology with precision is a challenge. The interpretation of agroecology in development has been divergent and contested, viewed variously as a set of practices, a social movement or the science of sustainable agriculture (Wezel et al. 2009, 2020). Moreover, differentiating agroecology from other forms of alternative agriculture for sustainability can be challenging due to vague or diverse definitions (Newton et al. 2020; Giller et al. 2021; Petersen and Snapp 2015). Box 1 provides examples of approaches to defining agroecology. Box 2 summarises major schemes for sustainable agriculture related to agroecology and climate change. All share the aim to reduce the negative impacts of agriculture, but approaches vary in their reliance on ecological processes, external inputs, whole system design, or emphasis on specific outcomes.
Box 1: Contemporary Approaches to Defining Agroecology
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Ten elements of agroecology: Diversity, the co-creation and sharing of knowledge, synergies, efficiency, recycling, resilience, human and social values, culture and food traditions, responsible governance, circular and solidarity economy
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Thirteen principles of agroecology (HLPE 2019, also summarised here): recycling, input reduction, soil health, animal health, biodiversity, synergy, economic diversification, the co-creation of knowledge, social values and diets, fairness, connectivity, land and natural resource governance, participation.
Gliessman (2018): “Agroecology is the integration of research, education, action and change that brings sustainability to all parts of the food system: ecological, economic, and social.” It is transdisciplinary, participatory, action-oriented and “grounded in ecological thinking where a holistic, systems-level understanding of food system sustainability is required.”
For this analysis, we considered approaches to be more agroecological to the extent that they made use of ecological processes, supported increasing autonomy from external inputs, or enabled whole system change, rather than focusing on changing single practices (Sinclair et al. 2019; Leippert et al. 2020). We focused on the biophysical science and practice aspects of agroecology to assess impacts on climate change adaptation and mitigation, and on drivers and enabling conditions of farmer behaviour for the analysis of scaling.
We identified agroecology practices and systems guided by the United Nations’ Food and Agriculture Organisation (FAO) 10 Elements of Agroecology and Gliessman’s (2016) transitions framework. To distinguish agricultural approaches aligned with agroecology, we considered field, farm and landscape-level approaches that relied on enhanced ecological processes and services, compared to business-as-usual agricultural development. Examples of the agroecology approaches reviewed included diversifying crop production through cover crops, green manure and hosts for beneficial insects; managing organic nutrient sources; biopesticides; crop-livestock integration; agroforestry and organic farming.
Box 2: Schemes for Sustainable Agriculture Related to Agroecology and Climate Change (Adapted from Petersen and Snapp 2015)
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Regenerative agriculture seeks “to improve the health of soil or to restore highly degraded soil, which symbiotically enhances the quality of water, vegetation and land-productivity” (Rhodes 2017). The potential to enhance soil carbon has recently made these practices more prominent in climate discussions.
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Sustainable intensification is the production of more food on a sustainable basis with minimal use of additional land (Baulcombe et al. 2009). It creates “synergistic opportunities for the co-production of agricultural and natural capital outcomes” (Pretty et al. 2020). Often associated with increased energy or fertiliser inputs and viewed as a means for sparing land, e.g., to avoid the conversion of forests.
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Ecological intensification “harness(es) biological understanding to improve agricultural system performance, both in terms of productivity and environmental services” (Petersen and Snapp 2015).
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Biodynamic farming involves “organic farming techniques that improve soil health” in ways that “influence biological as well as metaphysical aspects of the farm” (Ponzio et al. 2013). Developed by Rudolf Steiner.
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Organic agriculture is a production system that sustains the health of soils, ecosystems, and people. It relies on ecological processes, biodiversity and cycles adapted to local conditions, rather than inputs with adverse effects. Organic agriculture combines tradition, innovation, and science to benefit the shared environment and promote fair relationships and a good quality of life for all involved.
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Climate-smart agriculture is “agriculture that sustainably increases productivity, enhances resilience (adaptation), reduces/removes GHGs (mitigation) where possible, and enhances achievement of national food security and development goals” (Lipper et al. 2014).
The evidence for the review was based on the published scientific literature and semi-structured interviews with representatives from agricultural development programmes. For the literature review, we identified eighteen synthesis papers relevant to the impacts of agroecology on climate change adaptation and mitigation or to the scaling of agroecology, representing over 10,212 studies. Only four of the eighteen synthesis papers focused on LMICs, and only five others included at least 50% of the studies reviewed on LMICs, indicating the poor representation of LMICs for available syntheses in English. In addition, we conducted a systematic literature review of the primary evidence from LMICs for agroecological approaches and climate change outcomes related to nutrient management (15,674 articles) and pests and diseases (5,498 articles), resulting in a final selection of 138 papers representing about 20 agroecological practices. Of these papers, 71% represented data from Africa, 21% from Asia and 7% from Latin America, the latter suggesting the need for a similar review of the Spanish-language literature. One percent of the papers covered multiple regions. Seventy-eight percent of the papers addressed small farms, 9% addressed medium farms and 2% large farms. The full report is available online.
2 What Does the Evidence Tell Us?
2.1 Climate Change Adaptation
Substantial evidenceFootnote 1 exists in favour of climate change adaptation in LMICs that is associated with practices and systems aligned with agroecology, e.g., farm diversification,Footnote 2 agroforestry and organic agriculture (Fig. 1). The agroecological approach with the strongest body of evidence for its impacts on climate change adaptation was farm diversification (strong evidence and high agreement). This included positive impacts of diversification on crop yield, pollination, pest control, nutrient cycling, water regulation and soil fertility. This is consistent with a recent global systematic review of similar practices within smallholder agriculture (Reich et al. 2021).
We found profound evidence concerning the impacts of agroforestry and organic agriculture on adaptation. Agroforestry had a positive impact on biodiversity, water regulation, soil carbon, nitrogen and soil fertility and the buffering of temperature extremes (Beillouin et al. 2019; Niether et al. 2020; Kuyah et al. 2019). Organic agriculture improved regulating (pest, water, nutrient) and supporting services (soils, biodiversity) (Smith et al. 2019).
Very little information was found about how agroecological approaches can improve resilience to extreme weather, which may be partly due to the challenges of studying responses to erratic, rare events and the need for modelling and global analytical approaches that were outside the scope of the studies reviewed.
2.2 Climate Change Mitigation
Evidence regarding impacts on mitigation is modest,Footnote 3 except for enhanced carbon sequestration in soil and biomass (Fig. 1). The agroecological approach with the strongest body of evidence concerning its impacts on climate change mitigation was tropical agroforestry, which was associated with the sequestration of carbon in biomass and soil (medium evidence, high agreement) (Corbeels et al. 2019; Feliciano et al. 2018). Also, there is a moderate and growing body of evidence in favour of organic agriculture and associated gains in soil carbon, predominantly from temperate regions and high income countries (Gattinger et al. 2012; Smith et al. 2019).
For example, Gattinger et al. (2012) reported that soil carbon stocks were higher by 3.50 ± 1.08 Mg C ha−1, and soil carbon sequestration rates were higher by 0.45 ± 0.21 Mg C for pairwise comparisons of organic compared to non-organic farming, based on datasets from 74 studies. Nitrous oxide mitigation evidence was modest for tropical agriculture overall, and data on methane mitigation was very limited. Evidence from the global North suggests that reliance on organic nutrient sources and organic farming would likely avoid increased nitrous oxide emissions compared to the use of synthetic nitrogen fertiliser (medium evidence, medium agreement).
As the greenhouse gas (GHG) footprint of outcomes depends on where system boundaries are drawn, multi-scalar analysis is needed to capture flows of inputs and GHG impacts beyond the farm scale; for example, emissions associated with nutrient sources (e.g., industrial fertiliser production), land-use change or feed production (Connor 2018). The almost complete lack of data on tropical agriculture GHG emissions in agroecology exacerbates this research gap (Box 3).
Box 3: Evidence Used for the Assessment
To assess the evidence concerning the impact of agroecology on climate change outcomes, we compiled information from two sources and triangulated findings. We selected:
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1.
high-quality, peer-reviewed review papers relevant to agroecology and climate change adaptation and mitigation impacts or the scaling of agroecology; and
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2.
primary evidence in scientific papers on approaches aligned with agroecology for (a) nutrient management and (b) integrated pest and disease management.
For the primary evidence papers, studies were only selected for analysis if they also indicated an aspect of scaling up agroecology. Scaling was defined broadly, and included adoption, farmer innovation, scaling mechanisms or enabling conditions, learning, market or policy incentives and participatory research methods. For these papers, we documented the presence of indicators as evidence in favour of adaptation and mitigation impacts. This did not include whether impacts were positive or negative relative to a control.
We also conducted semi-structured interviews with twelve organisations involved in agricultural development in LMICs, including several organisations implementing agroecology at large scales. These interviews aimed to explore the conditions and constraints for scaling up agroecology, as experience with agroecology is still novel, and thus this information was not widely available in the scientific literature.
Evidence was evaluated based on its quality and the level of agreement based on Intergovernmental Panel on Climate Change (IPCC) guidance for conducting syntheses (Mastrandrea et al. 2010). The evaluation was qualitative and relative. The strength of evidence was based on the degree of scientific robustness (statistical significance, sample size, use of systematic comparison, pairwise comparison, number of articles), relevance to agroecology, extent of geographic representativeness, relevance to LMICs, and overall quality or credibility of an article. The level of agreement was generally “high” if there were more than 100 articles with strong evidence, “medium” if there were 50–99 articles with strong evidence, or “low” if there were less than 50 articles with strong evidence, or, in the case of interviews, where the majority of the respondents agreed.
2.3 Adaptive Capacity
Evidence suggests that agroecology provides more climate change adaptation and mitigation than conventional, higher-input agricultural development in LMICs by emphasising locally relevant solutions, participatory processes and the co-creation of knowledge as core values. Specifically, the co-creation and sharing of knowledge supported farmers’ capacity to adapt practices more successfully to local conditions (strong evidence, medium agreement). In addition, multiple lines of evidence have shown that engaging with local knowledge through participatory and educational approaches effectively adapts technologies to local contexts, and thereby delivers improved climate change adaptation and mitigation.
Most interview respondents agreed that system approaches that prioritised local adaptation provided substantial benefits for climate change outcomes, often more than single practices. One respondent explained that “farmers are inherently system-based, and adjusting to their reality has made the work effective and created more opportunities.”
2.4 Yields
Evidence concerning trade-offs between yields and climate change adaptation and mitigation exists, but was not systematically reported. There were win-win outcomes for yields and climate change mitigation associated with crop diversity and organic nutrient management. There was some evidence for modest trade-offs between yields and climate outcomes for organic farming and agroforestry. Diversification was associated with increased or maintained yields (although variable) compared to conventional agriculture (high evidence, high agreement). Conversely, variable and sometimes modestly lower yields were reported for organic agriculture (Skinner et al. 2014). Agroforestry systems had variable impacts on yield depending on the main crop, agroecological zone and soil type. For example, cocoa agroforestry produced lower cocoa yields, but higher overall yields from other crops in the system and improved climate change mitigation and adaptation (Niether et al. 2020). A review of agroforestry in sub-Saharan Africa found that agroforestry significantly increased yields and soil carbon (Kuyah et al. 2019).
2.5 Agroecological Transitions for Large-Scale Impacts
Evidence in the scientific literature relevant to scaling and enabling conditions of agroecology was poor, with only four relevant systematic reviews identified. The scientific robustness of the evidence was also mixed. Most reviews did not address agroecology at scale explicitly or compare the scaling conditions of agroecology and conventional agriculture. The literature review of primary evidence in favour of agroecology approaches to nutrient and pest management reported many of the same interventions and enabling conditions as those observed for scaling conventional agriculture interventions. These included the need for farmer capacity-building, use of markets, the necessity of involving government, the lack of cooperation between government offices of agriculture and offices of the environment, and poor implementation of policies (low evidence, medium agreement).
Based on interviews with field programmes, common components of these programmes’ efforts to bring agroecology to scale included the co-creation and exchange of knowledge with farmers, community-based, participatory methods, localised solutions and social organising. According to the literature, scaling agroecology systems, as opposed to practices, made more use of participatory and farmer-to-farmer processes and policy. Scaling also relied on market and policy measures that privileged local production. Agroecology’s inherent complexity and knowledge intensity sometimes incurred higher costs and more time than conventional agriculture, but this also enabled effectiveness and sustained benefits over multiple years.
Modest evidence was also found regarding disadvantages and challenges that impede agroecological transitions. Of the eighteen synthesis papers addressing agroecology and climate change impacts, only one explicitly addressed scaling (Cacho et al. 2018). Our review of the primary literature on nutrient and pest management yielded only 58 out of 138 articles on scaling-out processes, enabling conditions or barriers.
Critiques of agroecology have raised the issue of how to transition and reach large numbers of people. Compared to high-input sustainable intensification, agroecology can require more land to enable the use of ecosystem-based inputs and nutrient cycles (Connor 2018; Schreinemachers et al. 2011). The co-design of options with farmers can be slower and more costly for facilitating organisations, compared to top-down technical solutions, but farmers are also more likely to benefit. The attention to local knowledge around adaptation is, in this regard, both a strength and a challenge. Supporting local knowledge also requires a change in mindset of local and international actors involved in agricultural research and development and additional investment. Using conventional economic analysis, agroecological approaches can be more expensive, and some require more labour inputs compared to high-input agriculture optimised for yields; however, long-term and ecosystem benefits can be higher. The yield trade-offs associated with some agroecology approaches are a disadvantage and may pose a substantial challenge to adoption, particularly for farmers with limited resources in LMICs. Because of these constraints, the private sector has lacked incentives to facilitate agroecological practices.
2.6 Gaps
There is a need for research, especially in LMICs, that compares agroecology against alternatives, including current practices and expected trajectories in particular localities. More research is also needed for long-term studies on farms and at landscape scales in LMICs. A large data gap was found regarding agricultural GHG emissions and mitigation, with almost no evidence from LMICs. There were also evidence gaps regarding agroecology approaches involving livestock integration, landscape-scale redesign and multi-scalar analysis.
Critiques of agroecology question the extent to which scaling agroecology may restrict farmers’ options and become a poverty trap through a lack of access to growth opportunities (Mugwanya 2019). Similarly, to what extent does agroecology empower and enable farmer organisation? There is generally a lack of data or scenarios showing the impacts of agroecological transitions on economic development. A better understanding of the political economy of development, including who wins and who loses, and evaluation of the short-term and long-term social and ecological benefits and trade-offs of agroecology compared with other agricultural development approaches could help inform development investment. The Transformative Partnership Platform on agroecological approaches aims to contribute to this area by evaluating the socioeconomic viability of agroecological practices across Africa.
2.7 Donor Investment
Recent reviews of funding for agroecology found that most investments at least partly support agroecological principles (Biovision and IPES-Food 2020; CIDSE 2020). However, these analyses do not examine investments related to climate change adaptation or mitigation. The majority of agricultural investment (63%) is targeted at reinforcing or making minor adjustments to existing systems (sustainable intensification, separate funding mechanisms for agriculture and environment, performance measured mostly via yields) (Biovision and IPES-Food 2020), despite calls for food system transformation (Steiner et al. 2020). Funding for agroecology remains a small proportion of major global agricultural development investment.
To improve investment in agroecology for the sake of climate change, long-term funding modalities, the setting of targets for outcomes that include environmental services and climate change outcomes – in addition to nutritional and livelihood and social outcomes – and a search for systemic change to building farmer capacities and incentives are needed (Biovision and IPES-Food 2020). Rather than treating climate change adaptation and mitigation as co-benefits, which risks limiting progress to incremental change, there is a need to actively manage for climate change benefits. Key programme elements to increase support for agroecology and climate change outcomes include (Fig. 2):
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Processes for the co-design of practices by farmers, with research to generate relevance, fit the local context, and enable ongoing adaptation to climate risks, rather than pre-determined technical packages.
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Designing system approaches, including agroforestry, organic farming, diversification, integrated pest and soil management, and landscape management designed for flexibility so as to be contextually specific and effective for climate change mitigation and adaptation.
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Strengthening extension-farmer networks and farmer-based organisations to support finance, training, farmer-to-farmer knowledge exchange, local education, monitoring and decision-making.
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Market, institutional and policy arrangements that promote these approaches and overcome the tendency for environmental and climate change objectives to be treated as separate from agricultural development, and that address trade-offs between environment or social outcomes and productivity or profitability to support more rapid and large-scale impacts, including nationally determined contributions (NDCs) to the Paris Agreement.
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Providing institutional support for monitoring environmental services, in order to assess performance that considers more than productivity or profitability, using climate change mitigation and adaptation indicators. This is needed to inform policy across multiple dimensions and support annual reporting to the UN Framework Convention on Climate Change (UNFCCC).
2.8 What Actions Need to Be Taken?
Tackling climate change will require broad cooperation and diverse approaches. Implementing agroecology across organisations with different political visions for development will require transcending the many labels around sustainable agriculture and climate change (e.g., climate-smart agriculture, regenerative agriculture), including agroecology. Labels like agroecology can still be expedient for communication; the point is to spend less time debating what agroecology is.
We thus recommend an outcome-based approach to guide donor investment and national policy, using an assessment of the performance of agricultural development that integrates agroecological principles and climate change adaptation and mitigation indicators. This is to avoid contestation around what is encompassed by a specific label for an agricultural alternative and instead assess performance in terms of environmental services and climate change response. Attention to outcomes relevant to the Sustainable Development Goals (SDGs) such as climate change resilience, environmental health, gender equity and social inclusion, soil health, biodiversity conservation, healthy diets and resource efficiency can provide common points of reference (Leippert et al. 2020).
A number of frameworks can be used to systematise the monitoring of agroecology performance (Wezel et al. 2020; Kapgen and Roudart 2020), including FAO’s Tools for Agroecological Performance Evaluation (TAPE) (Barrios et al. 2020). The USAID-supported Sustainable Intensification Assessment Framework provides systematic approaches to outcome-based assessment and trade-off analysis (Grabowski et al. 2018).
Based on the strength of the evidence, a second important action is to direct agricultural development investments towards agricultural diversification, local adaptation and pathways to scaling both. Programme implementation experts indicated that promoting agricultural diversity can be a scalable intervention, and that it is often prioritised in programmes supporting agroecology. However, trends in agricultural development overall lean in the opposite direction, with widespread simplification of farms and cropping systems. Local adaptation can be promoted by supporting farmer innovation, co-learning and the adaptation of innovations to local contexts. Top-down technology packages are often promoted, rather than menus of farmer-co-designed options. Thus, diversification and local adaptation may require special attention at the policy and program levels.
In many countries, local and national agroecology platforms already exist, but can be strengthened to successfully use agroecology for climate change adaptation and mitigation in addition to the improvement of local livelihoods. Knowledge systems of agricultural producers need to be affirmed through networks of farmers and other stakeholders within the food systems to support the co-design of climate-friendly practices. To support farmer investment in diversified farms, women and men farmers’ access and control over land and other elements of agroecosystems will be key enabling conditions (FAO 2012).
The limited information concerning agroecological approaches’ response to extreme weather events and GHG emissions is a matter of great concern. A third action is to develop national strategies and action to enhance resilience to extreme weather events and climate change mitigation outcomes. This should build on the knowledge of countries with considerable experience of repeated extreme weather – such as the Philippines, Thailand, Haiti, and Honduras – to support strategies that will embed planning for extreme weather events in national policies. There is an urgent need to build the capacity of policymakers, scientists and institutions from the global South to work on these issues.
A fourth action is public investment in research to improve analysis of agroecology relative to other agriculture development approaches at multiple spatial and time scales so as to better evaluate alternative approaches to sustainable agriculture. Assessment is required for food security, environment and other dimensions of sustainable development, as well as the cost-effectiveness of different options in different contexts, including geographic regions. Assessment of cost-effectiveness should consider how to value environmental and social benefits and how assessment based on current policy contexts (e.g., subsidies) and short-time horizons might bias comparisons. Research includes comparative (alternatives versus conventional) and holistic (social, financial, environmental and agronomic) assessments. Reviews of French and Spanish-language literature would also enrich the foundation of evidence further, particularly for Latin America and West Africa.
Notes
- 1.
The number of articles with primary evidence from LMICs for adaptation was 120 out of 138, based on indicators of productivity (100), diversity (58), water and nutrient regulation (41), soil health (52), and pollination services and pest regulation (59). The quality and relevance of the eight synthesis papers found were mostly medium to high.
Two synthesis papers were found for diversification (covering crop diversification, organic farming, intercropping, accessory crops, and agroforestry) with 98 and 99 high-quality meta-analysis articles, respectively.
- 2.
“Agricultural diversification is the intentional addition of functional biodiversity to cropping [and livestock] systems at multiple spatial and/or temporal scales, and it aims at regenerating biotic interactions underpinning provisioning [regulating and supporting] …ecosystem services. It embraces a variety of practices encompassing the management of crops, noncrop habitats, soil, and landscapes.” Tamburini et al. 2020. Brackets added by brief authors.
- 3.
The number of articles with primary evidence from LMICs was limited: greenhouse gas emissions (6 articles), biomass carbon (4), and soil carbon (12), from a total of 138 articles. The quality and relevance of the six synthesis papers found were low to medium. Two synthesis papers were found for agroforestry, with 66 and 86 articles, respectively.
References
Barrios E, Gemmill-Herren B, Bicksler A et al (2020) The 10 elements of agroecology: enabling transitions towards sustainable agriculture and food systems through visual narratives. Ecosyst People 16(1):230–247. https://doi.org/10.1080/26395916.2020.1808705
Baulcombe D, Crute I, Davies B et al (2009) Reaping the benefits: science and the sustainable intensification of global agriculture. The Royal Society, London. https://royalsociety.org/~/media/royal_society_content/policy/publications/2009/4294967719.pdf
Beillouin D, Ben-Ari T, Makowski D (2019) Evidence map of crop diversification strategies at the global scale. Environ Res Lett 14(12). https://doi.org/10.1088/1748-9326/ab4449
Biovision, IPES-Food (2020) Money flows: what is holding back investment in agroecological research for Africa? Biovision Foundation for Ecological Development & International Panel of Experts on Sustainable Food Systems. https://www.agroecology-pool.org/moneyflowsreport
Cacho MMTY, Giraldo OF, Aldasoro M, Morales H et al (2018) Bringing agroecology to scale: key drivers and emblematic cases. Agroecol Sustain Food Syst 42:637. https://doi.org/10.1080/21683565.2018.1443313
CIDSE (2020) Finance for agroecology: more than just a dream? Policy briefing. Coopération Internationale pour le Développement et la Solidarité (CIDSE). https://www.arc2020.eu/wp-content/uploads/2020/10/CIDSE-Agroecology-and-Finance-Briefing-Sept-2020-1.pdf
Connor DJ (2018) Organic agriculture and food security: a decade of unreason finally implodes. Field Crop Res 225:128–129. https://doi.org/10.1016/j.fcr.2018.06.008
Corbeels M, Cardinael R, Naudin K, Guibert H, Torquebiau E (2019) The 4 per 1000 goal and soil carbon storage under agroforestry and conservation agriculture systems in sub-Saharan Africa. Soil Tillage Res 188:16–26. https://doi.org/10.1016/j.still.2018.02.015
FAO (2012) The voluntary guidelines on the responsible governance of tenure of land, fisheries and forests in the context of National Food Security. Food and Agriculture Organization of the United Nations (FAO), Rome. http://www.fao.org/3/i2801e/i2801e.pdf
Feliciano D, Ledo A, Hillier J, Nayak DR (2018) Which agroforestry options give the greatest soil and above ground carbon benefits in different world regions? Agric Ecosyst Environ 254:117–129. https://doi.org/10.1016/j.agee.2017.11.032
Gattinger A, Muller A, Haeni M et al (2012) Enhanced top soil carbon stocks under organic farming. Proc Natl Acad Sci U S A (PNAS) 109(44). https://doi.org/10.1073/pnas.1209429109
Giller K, Andersson J, Hijbeek R, Sumberg J (2021) Regenerative agriculture: an agronomic perspective. Outlook Agric 50. https://doi.org/10.1177/0030727021998063
Gliessman S (2016) Transforming food systems with agroecology. Agroecol Sustain Food Syst 40(3):187–189. https://doi.org/10.1080/21683565.2015.1130765
Gliessman S (2018) Defining agroecology. Agroecol Sustain Food Syst 42(6):599–600. https://doi.org/10.1080/21683565.2018.1432329
Grabowski P, Musumba M, Palm C, Snapp S (2018) Sustainable agricultural intensification and measuring the immeasurable: do we have a choice? In: Bell S, Morse S (eds) Routledge handbook of sustainability indicators and indices. Taylor and Francis Press, Oxfordshire, pp 453–476. https://doi.org/10.4324/9781315561103-29
HLPE (2019) Agroecological and other innovative approaches for sustainable agriculture and food systems that enhance food security and nutrition. A report by the High Level Panel of Experts on Food Security and Nutrition of the Committee on World Food Security, Rome
Kapgen D, Roudart L (2020) Proposal of a principle cum scale analytical framework for analyzing agroecological development projects. Agroecol Sustain Food Syst 44(7):876–901. https://doi.org/10.1080/21683565.2020.1724582
Kuyah S, Whitney CW, Jonsson M, Sileshi GW, Öborn I, Muthuri CW, Luedeling E (2019) Agroforestry delivers a win-win solution for ecosystem services in sub-Saharan Africa. A meta-analysis. Agron Sustain Dev 39(5):47. https://doi.org/10.1007/s13593-019-0589-8
Leippert F, Darmaun M, Bernoux M, Mpheshea M (2020) The potential of agroecology to build climate- resilient livelihoods and food systems. FAO and Biovision. https://doi.org/10.4060/cb0438en
Lipper L, Thornton P, Campbell B et al (2014) Climate-smart agriculture for food security. Nat Clim Chang 4:1068–1072. https://doi.org/10.1038/nclimate2437
Mastrandrea MD, Field CB, Stocker TF, Edenhofer O et al (2010) Guidance note for lead authors of the IPCC fifth assessment report on consistent treatment of uncertainties. Intergovernmental Panel on Climate Change (IPCC). https://archive.ipcc.ch/pdf/supporting-material/uncertainty-guidance-note.pdf
Mugwanya N (2019) Why agroecology is a dead end for Africa. Outlook Agric 48(2):113–116. https://doi.org/10.1177/0030727019854761
Newton P, Civita N, Frankel-Goldwater L, Bartel K, Johns C (2020) What is regenerative agriculture? A review of scholar and practitioner definitions based on processes and outcomes. Front Sustain Food Syst 4. https://doi.org/10.3389/fsufs.2020.577723
Niether W, Jacobi J, Blaser WJ, Andres C, Armengot L (2020) Cocoa agroforestry systems versus monocultures: a multi-dimensional meta-analysis. Environ Res Lett 15(10). https://doi.org/10.1088/1748-9326/abb053
Petersen B, Snapp S (2015) What is sustainable intensification: views from experts. Land Use Policy 58:1–10. https://doi.org/10.1016/j.landusepol.2015.02.002
Ponzio C, Gangatharan R, Neri D (2013) Organic and biodynamic agriculture: a review in relation to sustainability. Int J Plant Soil Sci 2(1):95–110. https://journalbank.org/IJPSS/article/view/1432/2860
Pretty J, Benton TG, Bharucha ZP et al (2020) Global assessment of agricultural system redesign for sustainable intensification. Nat Sustain 1:441–446. https://doi.org/10.1038/s41893-018-0114-0
Reich J, Paul SS, Snapp SS (2021) Highly variable performance of sustainable intensification on smallholder farms: a systematic review. Glob Food Sec 30. https://doi.org/10.1016/j.gfs.2021.100553
Rhodes CJ (2017) The imperative for regenerative agriculture. Sci Prog 100(1):80–129. https://doi.org/10.3184/003685017X14876775256165
Schreinemachers P, Sringarm S, Sirijinda A (2011) The role of synthetic pesticides in the intensification of highland agriculture in northern Thailand. Crop Prot 30(11):1430–1437. https://doi.org/10.1016/j.cropro.2011.07.011
Sinclair F, Wezel A, Mbow C, Chomba S, Robiglio V, Harrison R (2019) The contribution of agroecological approaches to realizing climate-resilient agriculture. Rotterdam and Washington, DC. Available online at www.gca.org
Skinner C, Gattinger A, Muller A et al (2014) Greenhouse gas fluxes from agricultural soils under organic and non-organic management — a global meta-analysis. Sci Total Environ 468–469:553–563. https://doi.org/10.1016/j.scitotenv.2013.08.098
Smith OM, Cohen AL, Rieser CJ et al (2019) Organic farming provides reliable environmental benefits but increases variability in crop yields: a global meta-analysis. Front Sustain Food Syst 3:82. https://doi.org/10.3389/fsufs.2019.00082
Steiner A, Aguilar G, Bomba K et al (2020) Actions to transform food systems under climate change. CGIAR Research Program on Climate Change, Agriculture and Food Security (CCAFS), Wageningen. https://hdl.handle.net/10568/108489
Tamburini G, Bommarco R, Wanger TC et al (2020) Agricultural diversification promotes multiple ecosystem services without compromising yield. Sci Adv 6(45). https://doi.org/10.1126/sciadv.aba1715
Wezel A, Bellon S, Doré T et al (2009) Agroecology as a science, a movement and a practice. A review. Agron Sustain Dev 29:503–515. https://doi.org/10.1051/agro/2009004
Wezel A, Herren BG, Kerr RB et al (2020) Agroecological principles and elements and their implications for transitioning to sustainable food systems. A review. Agron Sustain Dev 40(6):40. https://doi.org/10.1007/s13593-020-00646-z
Acknowledgements
We would like to thank Ajay Vir Jakhar, Alan Tollervey, Alesha Miller, Anna De Palma, Barbara Gemmil- Herren, Batamaka Somé, Boru Douthwaite, Bruce Campbell, Christian Huyge, Christian Witt, Christophe Larose, Daniel France van Gilst, Dhanush Dinesh, Diana Salvemini, Emily Weeks, Fabio Leippert, Giles Henley, Guy Faure, Howard Standen, James Birch, Jean-Francois Soussana, Jerry Glover, Joanna Francis, Julian Gonzalez, Mercedes Bustamante, Michael Farrelly, Michael Okoti, Nick Remple, Noel Gurwick, Rachel Lambert, Rikin Gandhi, Stephanie Heiland, Tom Tomich, Ueli Mauderli, Vijay Kumar, Wijnand Van Ijssel, Ken Giller, Confidence Duku, Annemarie Groot, and Joachim von Braun. This work was funded by the New Venture Fund and the CGIAR Research Program on Climate Change, Agriculture and Food Security (CCAFS), which is carried out with support from the CGIAR Trust Fund and through bilateral funding agreements. For details, please visit https://ccafs.cgiar.org/donors. The views expressed in this document cannot be taken to reflect the official opinions of these organisations.
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Snapp, S. et al. (2023). Delivering Climate Change Outcomes with Agroecology in Low- and Middle-Income Countries: Evidence and Actions Needed. In: von Braun, J., Afsana, K., Fresco, L.O., Hassan, M.H.A. (eds) Science and Innovations for Food Systems Transformation. Springer, Cham. https://doi.org/10.1007/978-3-031-15703-5_28
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