Sustainable Agricultural Practices: Navigating the Nexus of Innovation, Resilience, and Global Food Security Fish
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Abstract
This study explores the intricate nexus of innovation, resilience, and global food security within the domain of sustainable agriculture. Utilizing a mixed-methods research design, the research investigates the impact of technological innovations, specifically precision farming, AI integration, and genetic engineering, on agricultural productivity and resilience to climate change. Additionally, it analyzes socio-economic dimensions, including community involvement and livelihood impact. The findings indicate a positive correlation between technological adoption and productivity, highlighting precision farming as a key contributor. Moreover, the study emphasizes the role of technology in enhancing agricultural resilience to climate change. Positive socio-economic perceptions underscore the broader impact of sustainable practices on communities. Comparisons with previous studies reveal both consistencies and nuanced contributions, positioning this research as a significant addition to the evolving discourse on sustainable agriculture.
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References
Chen, Y., & Gupta, R. (2021). Blockchain in Sustainable Agriculture: Enhancing Transparency in Supply Chain Management. Sustainability, 13(11), 6102.
D Brown, J., & Greenfield, T. (2023). Beyond Limits: A Meta-Analysis of Traditional Agricultural Systems. Journal of Agricultural Science, 45(3), 289-305.
FAO. (2021). Sustainable Land Management for Climate Resilience. Food and Agriculture Organization. Retrieved from http://www.fao.org/sustainable-land-management
IPCC. (2023). Climate Change 2023: The Physical Science Basis. Intergovernmental Panel on Climate Change. Retrieved from https://www.ipcc.ch/report/ar6/wg1/
Johnson, Mark, Anderson, Emily, Smith, Richard, & Davis, Sarah. (2019). Diversified Farming Systems: Economic Viability and Resilience. Agricultural Economics, 51(3), 423–435.
Lou, C., Zhang, H., Wang, Y., & Chen, J. (2024). Agroecology and Biodiversity: A Path to Sustainable Agriculture. Ecological Applications, 34(2), 412-428.
Martinez, A., & Singh, S. (2020). Ecological Implications of Modern Agricultural Practices. Environmental Science and Technology, 44(7), 2653–2659.
Reynolds, H., & Nguyen, P. (2018). Social Dimensions of Sustainable Agriculture: The Role of Community Engagement. Sociology Ruralis, 58(2), 334–352.
Robertson, A., & Diaz, M. (2023). Precision Farming: Maximizing Efficiency in Agricultural Practices. Journal of Agricultural Technology, 56(1), 67-82.
Smith, R., Johnson, M., Brown, A., & Davis, S. (2021). Global Food Demand Projections for 2050. Journal of Agricultural Economics, 43(4), 567-580.
Wang, L., & Li, Z. (2022). Agroforestry Systems: Enhancing Climate Resilience in Agriculture. Journal of Environmental Management, 298, 113486.
WHO. (2022). Shifting Dietary Patterns and Non-Communicable Diseases. World Health Organization. Retrieved from https://www.who.int/news-room/questions-and-answers/item/dietary-patterns