Abstract
Climate change represents a serious threat to African agriculture, consequently leading to water scarcity and climate variability. These challenges negatively impact agricultural production. Climate-smart Agriculture (CSA) technologies, such as drought-tolerant seed varieties (DTSVs), can provide a solution. However, effective adoption and use of these technologies within smallholder communities is not straight forward. This study investigated the factors determining adoption of CSA technologies by exploring the farmers’ characteristics, contextual factors, and considered additional factors extracted from farmers’ perceptions of CSA technology-specific attributes. The study was carried out in Limpopo Province, South Africa. Quantitative and qualitative data from farmers’ cross-sectional survey (n=196) and focused group discussions (n=5), was subjected to descriptive and inferential statistical analysis. Factor analysis reduced 19 identified CSA technologies specific attributes to 5 factors that were used in the multinomial logistic regression model. Results show a range of drivers and barriers influencing DTSVs adoption. The adoption of DTSVs by sampled smallholder farmers were influenced by training and demonstration; knowledge and benefits related to DTSVs; necessary requirements like receiving tractor services on time, knowledge on better dates of DTSVs and weather information; enabling factors like additional training on DTSVs and information including knowledge about other CSA technologies other than DTSVs, gender, marital status and credit access. These results have policy implications for various stakeholders which reinforce multi-actor approach to climate change adaptation and building of functional institutions, enhancing training of smallholder farmers, improving on access to sufficient demonstrations, climate change information and credit support amongst other support. Key words: Climate smart agriculture, smallholder farmers, drought-tolerant seeds technology adoption, multinomial logit regression.
Highlights
Climate change represents a serious threat to the agricultural sector, requiring resilience to climate impacts and reductions in greenhouse gas (GHG) emissions
This study focuses on drought-tolerant seed varieties (DTSVs) for maize as a climate-smart agriculture (CSA) technology relevant for smallholder farmers in rain-fed crop production (Asayehegn et al, 2017; Senyolo et al, 2018)
The 5 factors extracted explained 63% of the variance in the 19 CSA technology specific characteristic components. These factors are: Factor 1: Training and demonstration related to DTSVs, accounts for 23.7% of the variance
Summary
Climate change represents a serious threat to the agricultural sector, requiring resilience to climate impacts and reductions in greenhouse gas (GHG) emissions. The main challenge facing agriculture concerning adaptation and mitigation is that more food which is produced efficiently under highly unpredictable conditions with net reductions in GHG emissions from production and marketing is needed. A prominent approach is climate-smart agriculture (CSA), which attempts to sustainably increase agricultural productivity, food security and incomes through adaptation and enhancing resilience to climate change as well as by reducing GHG emissions (Arslan et al, 2015; FAO, 2010, 2013). CSA can help to achieve the development goals of vulnerable populations who depend on agriculture (Partey et al, 2018), but this will involve effective management of synergies and trade-offs between mitigation, adaptation and productivity goals
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