Costs and benefits of climate-smart agriculture: The case of the Dry Corridor in Guatemala

Saín, Gustavo; Loboguerrero, Ana María; Corner-Dolloff, Caitlin; Lizarazo, Miguel; Nowak, Andreea; Barón, Deissy Martínez; Andrieu, Nadine

doi:10.1016/j.agsy.2016.05.004

Cited by 111 publications

(71 citation statements)

References 29 publications

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“…Climate-smart agriculture or climate-friendly agriculture (Żukowska et al, 2016) is introduced as a sustainable approach to promote adaptation-mitigation synergies (FAO, 2017c;Chandra et al, 2017) and minimize the negative impacts by integrating the concerns for food security (Arslan et al, 2017;Żukowska et al, 2016). Climate-smart agriculture, as defined and presented by FAO in 2010 (FAO, 2010;Żukowska et al, 2016), aims at sustainably increasing food security and incomes, adapting and building resilience to climate change, and reduce and or remove greenhouse gasses emission, where possible (FAO, 2017b; Chandra et al, 2016;FAO, 2017c;Sain et al, 2017). According to this definition, climate-smart agriculture has three dimensions i.e.…”

Section: Literature Reviewmentioning

confidence: 99%

Economic Modeling of Climate-Smart Agriculture in Iran

2019

New Medit

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Global warming is the immediate consequence of increased greenhouse gasses emission. Agriculture is a significant source in terms of greenhouse gasses emission and on the other hand, the main sector in terms of producing food. As global food demand grows, the share of agriculture in the total greenhouse gasses emission will rise too. Therefore, agriculture needs to cut the greenhouse gasses emission. A response to the two important issues today, i.e. achieving food security and reducing greenhouse gasses emission is climate-smart agriculture. According to the Paris Agreement, an international effort to reduce greenhouse gasses emission, Iran has to decrease 12 percent of its greenhouse gasses emission by 2050, which all sectors have to contribute. Since the pathway to define strategies, is to explore the challenges; in this study, a seemingly unrelated regression technique has been used to model the climate-smart agriculture in Iran. Three main sub-sectors of agriculture; i.e. crops, livestock, and aquatics production, have been considered in the model to find the role of them in delivering food security and emitting greenhouse gasses. The findings show livestock and aquaculture sectors have had a positive significant impact in achieving food security. On the other hand, these sectors have had a positive significant effect on the emitting greenhouse gasses. Cropping system was not found to have a significant role in achieving food security and emitting greenhouse gasses in Iran although the expected signs (+) has been confirmed by the model. New research to explore appropriate technical and behavioral innovations needs to do on the specific-product-sector to be climate-friendly and sustainable. On the consumers hand, an encouragement to a more healthy diet with more vegetable, where is possible, also can reduce emissions. Finally, the key message from the assessments is the future legislative outlines for mitigation, adaptation and resource management as well as consumer behavior for how agriculture can deal with climate change.

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Section: Literature Reviewmentioning

confidence: 99%

Economic Modeling of Climate-Smart Agriculture in Iran

2019

New Medit

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“…Specifically, structurally heterogeneous farms with on‐farm trees can attract more bird, whereas diversifying crops and cover types, and maintaining thicker hedgerows, will enhance bird and predatory arthropod diversity (Lichtenberg et al., ). By contrast, monocultures under conventional farming are susceptible to pest population build‐ups or invasions, due to reduced niches for species (Rusch et al., ; Sain et al., ). On‐farm trees are particularly important for attracting narrow‐ranging insectivorous birds, whose predation on crop herbivores can be more impactful due to their localized, intensive foraging habits.…”

Section: Resultsmentioning

confidence: 99%

“…Specifically, structurally heterogeneous farms with on-farm trees can attract more bird, whereas diversifying crops and cover types, and maintaining thicker hedgerows, will enhance bird and predatory arthropod diversity (Lichtenberg et al, 2017). By contrast, monocultures under conventional farming are susceptible to pest population build-ups or invasions, due to reduced niches for species (Rusch et al, 2016;Sain et al, 2017).…”

Section: Con Clus Ionsmentioning

confidence: 99%

Maize‐field complexity and farming system influence insectivorous birds’ contribution to arthropod herbivore regulation

2019

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The contribution of insectivorous birds to reducing crop damage through suppression of herbivory remains underappreciated, despite their role as cropland arthropod predators. We examined the roles of farming system, crop cover pattern, and structural configuration in influencing assemblage composition of insectivorous birds and their herbivorous arthropod prey across maize fields, and determined how bird exclusion affects crop herbivory levels. To achieve these objectives, we collected data across a sample of organic and conventional small‐scale non‐Bt maize farms in western Kenya. Assessments of abundance, diversity, and richness of insectivorous birds and abundance of their arthropod prey were compared between organic and conventional small‐scale non‐Bt maize on monocultured and inter‐cropped farms. We also employed bird exclusion experiments to assess impacts of bird predation on herbivorous arthropod abundance. Results showed that higher structural heterogeneity supported higher insectivorous bird richness, particularly under organic systems, dense trees, large woodlots, and thick hedgerows. Bird abundance further increased with crop diversity but not in relation to cropping method, hedgerow type, or percent maize cover per se. Conversely, herbivorous arthropod abundance and richness increased on conventional farms and those with higher percent maize cover, but were unaffected by cropping methods, tree, or hedgerow characteristics. Birds’ arthropod prey was more abundant under completely closed experimental plots compared with open or semi‐closed plots, confirming a significant linkage between birds and herbivorous arthropod suppression. In this study, we demonstrate importance of structural heterogeneity in agricultural landscapes, including diverse croplands and on‐farm trees to maximize insectivorous birds’ contribution to reducing crop arthropod herbivory. Abstract in Swahili is available with online material.

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“…In Guatemala, a dry corridor is "a semi-arid territory characterized by prolonged droughts, a broken topography consisting of hills and mountains, shallow soils with medium to low fertility rates and a tendency for erosion" (PNUD, 2013). The Dry Corridor experienced severe drought in the past decades for which the government of Guatemala provided emergency food aid and promoted the adaptation through agricultural practices that would mitigate the impact of drought, particularly to the most food insecure families (Sain et al, 2017). Several reports of Climate Change and its effect indicate that the rural area of the dry corridor will be most affected by droughts consequently families could be exposed to crops losses and lack of food and water (Castellanos and Guerra, 2009;Gutiérrez and Espinoza, 2010;Bouroncle et al, 2015;United Nations, 2018).…”

Section: Location Of the Study Area: Dry Corridormentioning

confidence: 99%

Agroforestry systems provide firewood for livelihood improvement in Guatemala

Sibelet¹,

Posada

Gutiérrez-Montes

2019

Bois for. trop.

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Dans le contexte du changement climatique et de la pauvreté, les populations rurales sont de plus en plus confrontées aux défis de la gestion adéquate des ressources, de la production alimentaire et de l’amélioration de la qualité de vie. Le Guatemala doit faire face au changement climatique et à la pauvreté tout en tenant compte de sa production agricole. À cet égard, les systèmes agroforestiers ont été proposés comme méthode alternative de production durable. Cet article présente une comparaison entre les systèmes agricoles conventionnels et les systèmes agroforestiers enrichis de Camotán et Jocotán. Les résultats montrent que le système agroforestier enrichi contribue à 65 % du bois-énergie contre 7 % pour le système conventionnel. Les familles utilisant le système agricole conventionnel ont extrait 81 % de leur bois-énergie de la forêt, alors que les familles utilisant le système agroforestier enrichi n’en ont extrait que 32 %. Le bois-énergie produit par le système agroforestier enrichi offre un avantage supplémentaire aux femmes, aux enfants et aux jeunes, qui sont chargés de transporter les fagots, car ils n’ont pas à parcourir de longues distances pour approvisionner le foyer. Les familles ont construit et adapté des connaissances empiriques sur la gestion des arbres dans leurs systèmes de culture. Le système agroforestier enrichi est donc présenté comme une solution potentielle pour répondre à la demande annuelle de bois-énergie. La sécurité foncière influence la décision des familles rurales d’investir ou d’innover. Les systèmes agroforestiers jouent un rôle clef dans l’augmentation des ressources et l’amélioration de la qualité de vie.

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Costs and benefits of climate-smart agriculture: The case of the Dry Corridor in Guatemala

Cited by 111 publications

References 29 publications

Economic Modeling of Climate-Smart Agriculture in Iran

Economic Modeling of Climate-Smart Agriculture in Iran

Maize‐field complexity and farming system influence insectivorous birds’ contribution to arthropod herbivore regulation

Agroforestry systems provide firewood for livelihood improvement in Guatemala

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