Climate-smart agricultural (CSA) interventions often require “fine-tuning” i.e. feedback from multiple stakeholders e.g. farmers, extension agents, NGO workers, and policy implementers on their relevance in a given context.
Getting essential feedback to ensure projects are on track in a timely w...
CSA and its principles: food security, mitigation, and adaptation, have been widely recognized as key elements for decision makers to include to meet the Sustainable Development Goals. Yet implementing successful innovations on a wider scale across nations – and even geographies – remains a chall...
Mwongera, Caroline
,
Läderach, Peter
,
Acosta, Mariola
,
Ampaire, Edidah L.
,
Eitzinger, Anton
,
Lamanna, Christine
,
Mwungu, Chris Miyinzi
,
Shikuku, K.M.
,
Twyman, Jennifer
,
Winowiecki, Leigh A.
,
[Nine ways to make agriculture more climate-smart]
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Nine ways to make agriculture more climate-smart
A robust, resilient, and enabling policy environment is critical to take agriculture innovations to scale at national or regional level.
Policy formulation processes that consider climate variability, socioeconomic and environmental shocks require participatory, inclusive, and explorative scenari...
Better soil health can increase agricultural productivity. Restoration activities can build on-farm resilience and contribute to climate change adaptation and mitigation.
Land and soil health surveys can improve crop modeling predictions under various climate scenarios and guide more targeted in...
Winowiecki, Leigh A.
,
Mwongera, Caroline
,
Läderach, Peter
,
Acosta, Mariola
,
Ampaire, Edidah L.
,
Eitzinger, Anton
,
Lamanna, Christine
,
Mwungu, Chris Miyinzi
,
Shikuku, K.M.
,
Twyman, Jennifer
,
[Invest in climate-smart soil and land health]
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Invest in climate-smart soil and land health
The process of getting climate-smart agricultural (CSA) interventions and practices to farmers is just as important as the interventions and practices.
Given the complex systems in which CSA is implemented and the various CSA practices and technologies, there is no one-size-fits-all scaling path...
Mwongera, Caroline
,
Mwungu, Chris Miyinzi
,
Läderach, Peter
,
Acosta, Mariola
,
Ampaire, Edidah L.
,
Eitzinger, Anton
,
Lamanna, Christine
,
Shikuku, K.M.
,
Twyman, Jennifer
,
Winowiecki, Leigh A.
,
[Target the pathways to scale out climate-smart agricultural technologies to farming communities]
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Target the pathways to scale out climate-smart agricultural technologies to farming communities
Recognizing successful climate-smart agricultural (CSA) practices is not enough for them to be adopted at scale.
At many sites, government or development-led interventions to promote CSA practices face low adoption rates or are not adopted at all.
Data shows that CSA adoption depends on drivers...
Läderach, Peter
,
Mwongera, Caroline
,
Lamanna, Christine
,
Acosta, Mariola
,
Ampaire, Edidah L.
,
Eitzinger, Anton
,
Mwungu, Chris Miyinzi
,
Shikuku, K.M.
,
Twyman, Jennifer
,
Winowiecki, Leigh A.
,
[Know what drives the adoption of climate-smart agriculture across different scales]
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Know what drives the adoption of climate-smart agriculture across different scales
Research suggests that farmer-to-farmer learning can be up to six times more effective in spreading knowledge of CSA practices than in areas where it is not carried out.
Understanding the wider context and requirements for social learning is key.
Peer learning is an effective way to disseminate C...
Shikuku, K.M.
,
Mwongera, Caroline
,
Läderach, Peter
,
Acosta, Mariola
,
Ampaire, Edidah L.
,
Eitzinger, Anton
,
Lamanna, Christine
,
Mwungu, Chris Miyinzi
,
Twyman, Jennifer
,
Winowiecki, Leigh A.
,
[Support farmer-to-farmer and community-wide social learning]
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Support farmer-to-farmer and community-wide social learning
Research suggests that gender equity is a critical factor in the adoption of climate-smart agricultural (CSA) practices.
If gender is not explicitly considered in climate-related interventions, the adoption of climate-resilient practices is unlikely to reach scale.
Climate-resilient interventio...
Twyman, Jennifer
,
Mwongera, Caroline
,
Läderach, Peter
,
Acosta, Mariola
,
Ampaire, Edidah L.
,
Eitzinger, Anton
,
Lamanna, Christine
,
Mwungu, Chris Miyinzi
,
Shikuku, K.M.
,
Winowiecki, Leigh A.
,
[Design climate-smart agricultural interventions to be gender inclusive]
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Design climate-smart agricultural interventions to be gender inclusive
Research shows that climate-smart agriculture (CSA) is beneficial in increasing productivity, promoting resilience and reducing greenhouse gas emissions.
Achieving benefits in all three dimensions is difficult, and so necessary choices among competing investments and objectives must be made.
The ...
Mwongera, Caroline
,
Läderach, Peter
,
Acosta, Mariola
,
Ampaire, Edidah L.
,
Eitzinger, Anton
,
Lamanna, Christine
,
Mwungu, Chris Miyinzi
,
Shikuku, K.M.
,
Twyman, Jennifer
,
Winowiecki, Leigh A.
,
[Assess whole-farm trade-offs and synergies for climate-smart agriculture]
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Assess whole-farm trade-offs and synergies for climate-smart agriculture
Clearly showing the benefits of certain climate-smart agricultural (CSA) interventions over others in a particular context is key to facilitating prudent investment of scarce resources.
Ranking certain CSA practices over others is complex because CSA implies multiple outcomes, which vary with co...
Lamanna, Christine
,
Mwongera, Caroline
,
Läderach, Peter
,
Acosta, Mariola
,
Ampaire, Edidah L.
,
Eitzinger, Anton
,
Mwungu, Chris Miyinzi
,
Shikuku, K.M.
,
Winowiecki, Leigh A.
,
[Prioritize among climate-smart agricultural options and benefits for greater impact]
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Prioritize among climate-smart agricultural options and benefits for greater impact