Economic development of agriculture in Kazakhstan in the context of climate change

Purpose – The study explores rising climate fluctuations in Kazakhstan, focusing on agriculture’s resilience; it highlights consequences for income security, village communities, or future planning.

Methodology – This research uses descriptive methods alongside comparison techniques, relying on existing data. It examines patterns in rising temperatures, shifts in rainfall, more frequent droughts, declining soil quality, or limited water access. These environmental factors are then connected to how well farming performs over time.

Originality / value – The study adds to existing work on climate risks in Central Asia by linking environmental, financial, and sector-level factors into one analysis approach while using varied structural choices per sentence. A rare look at how farming and climate interact in Kazakhstan is provided, showing local adaptation efforts already tested in real conditions instead of relying on generic solutions.

Findings – Results indicate rising heat stress, less rain, frequent droughts, and growing dry areas reduce crop output, animal performance, or soil health, thus harming food access plus income in rural regions. The study highlights key adaptive actions like smart irrigation tools, varied farming setups, or sturdy equipment and methods which may improve resistance while aiding lasting growth.

1. The World Bank. (2025). Agriculture, forestry and fisheries, value added (% of GDP) [Dataset]. The World Bank. https://data.worldbank.org/indicator/NV.AGR.TOTL.ZS

2. Chanchal, C., Sharma, R., Bhushan, H., Kumar, V., Kumari, D., Brahma, U., & Ram, K. (2025). Impact of climate change on agriculture and adaptive strategies: A comprehensive review. AATCC Review, 13(1), 312–323. https://doi.org/10.21276/aatccreview.2025.13.01.311

3. Pratap, D., Tamuly, G., N R, G., Anbarasan, S., Pandey, A. K., Singh, A. P., Debnath, A., & Iberaheem, M. (2024). Climate change and global agriculture: Addressing challenges and adaptation strategies. Journal of Experimental Agriculture International. https://doi.org/10.9734/jeai/2024/v46i62533

4. Verma, S., Singh, A., Pradhan, S. S., & Kushuwaha, M. (2024). Impact of climate change on agriculture: A review. International Journal of Environment and Climate Change. https://doi.org/10.9734/ijecc/2024/v14i34069

5. Liu, Y., Geng, X., Hao, Z., & Zheng, J. (2020). Changes in climate extremes in Central Asia under 1.5 and 2 °C global warming and their impacts on agricultural productions. Atmosphere, 11(10), 1076. https://doi.org/10.3390/ATMOS11101076

6. Aleksandrova, M. (2015). Water scarcity under climate change: Impacts, vulnerability and risk reduction in the agricultural regions of Central Asia. http://dspace.unive.it/handle/10579/5600

7. Sutton, W. R., Srivastava, J. P., & Neumann, J. E. (2013). Looking beyond the horizon: How climate change impacts and adaptation responses will reshape agriculture in Eastern Europe and Central Asia. World Bank. https://doi.org/10.1596/978-0-8213-9768-8

8. Baspakova, G. R., Nyssanbayeva, A. S., & Tursynbay, A. A. (2025). Оценка воздействия изменения климата на интенсивность и частоту засух в Южном Казахстане. География и водные ресурсы, 2, 73– 85. https://doi.org/10.55764/2957-9856/2025-2-73-85.22

9. Sadrtdinova, R., Corzo Perez, G. A., & Solomatine, D. P. (2024). Improved drought forecasting in Kazakhstan using machine and deep learning: A non-contiguous drought analysis approach. Hydrology Research. https://doi.org/10.2166/nh.2024.154

10. Tian, L., Ho, S., Disse, M., & Tuo, Y. (2021). The temporal propagation processes of multiple types of drought in Central Asia. https://doi.org/10.5194/EGUSPHERE-EGU21-6499

11. Vakulchuk, R., Daloz, A. S., Overland, I., Sagbakken, H. F., & Standal, K. (2022). A void in Central Asia research: Climate change. Central Asian Survey, 42(1), 1–20. https://doi.org/10.1080/02634937.2022.2059447

12. Kabdullina, G. K., & Kabdolla, A. (2025). The impact of pasture degradation on the sustainability of food security in the regions of Kazakhstan. 2(17), 43–53. https://doi.org/10.71050/2305-3348.2025.17.2.006

13. Larson, D. F., Dinar, A., & Blankespoor, B. (2012). Aligning climate change mitigation and agricultural policies in Eastern Europe and Central Asia. World Bank. https://doi.org/10.1596/1813-9450-6080

14. Steenwerth, K. L., Hodson, A. K., Bloom, A. J., Carter, M. R., Cattaneo, A., Chartres, C. J., Hatfield, J. L., Henry, K., Hopmans, J. W., Horwath, W. R., Jenkins, B. M., Kebreab, E., Leemans, R., Lipper, L., Lubell, M., Msangi, S., Prabhu, R., Reynolds, M. P., Sandoval Solis, S., … Jackson, L. E. (2014). Climate-smart agriculture global research agenda: Scientific basis for action. Agricultural and Food Science, 3(1), 11. https://doi.org/10.1186/2048-7010-3-11

15. StatGov. (2025). Statistics of agriculture, forestry, hunting and fishing. Dynamic series [Dataset]. Agency for Strategic Planning and Reforms of the Republic of Kazakhstan Bureau of National Statistics. https://stat. gov.kz/ru/industries/business-statistics/stat-forrest-village-hunt-fish/dynamic-tables/

16. Cousin, M., & Rush, J. (2025). Temperature rising (pp. 79–94). https://doi.org/10.1093/9780197800942.003.0007

17. Tong, G., Chung, J., Zhang, M., Lin, W. Y., Zhang, T., Bentler, P. M., & Zhu, W. (2023). Data driven pathway analysis and forecast of global warming and sea level rise. Dental Science Reports, 13(1). https://doi.org/10.1038/s41598-023-30789-4

18. NCEI. (2025). NOAA Global Surface Temperature Dataset (NOAAGlobalTemp), version 6.0 [Dataset]. https://www.ncei.noaa.gov/data/noaa-global-surface-temperature/v6/access/timeseries/

19. Chaudhary, K. B., Trivedi, A. P., Macwan, S. J., & Barvaliya, P. P. (2025). Effect of temperature rise on crop growth and productivity. International Journal of Environment and Climate Change, 15(1), 167– 177. https://doi.org/10.9734/ijecc/2025/v15i14683

20. Bowling, L. C., Cherkauer, K. A., Lee, C. I., Beckerman, J. L., Brouder, S. M., Buzan, J. R., Doering, O. C., Dukes, J. S., Ebner, P. D., Frankenberger, J. R., Gramig, B. M., Kladivko, E. J., & Volenec, J. J. (2020). Agricultural impacts of climate change in Indiana and potential adaptations. Climatic Change, 163(4), 2005–2027. https://doi.org/10.1007/S10584-020-02934-9

21. Key, N., & Sneeringer, S. (2014). Greater heat stress from climate change could lower dairy productivity. Amber Waves, 10, 1. https://doi.org/10.22004/AG.ECON.210018

22. Key, N., Sneeringer, S., & Marquardt, D. (2014). Climate change, heat stress, and U.S. dairy production. Social Science Research Network. https://doi.org/10.22004/AG.ECON.186731

23. Lal, R. (2012). Climate change and soil degradation mitigation by sustainable management of soils and other natural resources. Agricultural Research, 1(3), 199–212. https://doi.org/10.1007/S40003-012-0031-9

24. Gupta, G. S. (2019). Land degradation and challenges of food security. Review of European Studies, 11(1), 63. https://doi.org/10.5539/RES.V11N1P63

25. Dharumarajan, S., Veeramani, S., Beeman, K., Lalitha, M., Janani, N., Srinivasan, R., & Hegde, R. (2019). Potential impacts of climate change on land degradation and desertification: Land degradation and climate change (pp. 183–195). IGI Global. https://doi.org/10.4018/978-1-5225-7387-6.CH010

26. Badapalli, P. K., Babu, K. R., & Pujari, P. S. (2023). Land degradation and desertification (pp. 13–49). Springer Nature. https://doi.org/10.1007/978-981-99-6729-2_2

27. Vitkovskaya, I., Batyrbayeva, M., Berdigulov, N., & Mombekova, D. (2024). Prospects for drought detection and monitoring using long-term vegetation indices series from satellite data in Kazakhstan. Land, 13(12), 2225. https://doi.org/10.3390/land13122225

28. Çuhadar, M. (2024). The impact of drought on agricultural production and agricultural adaptation to drought (pp. 83–107). https://doi.org/10.69860/nobel.9786053359432.5

29. Yilmaz, G. (2023). Kuraklık ve sıcak hava dalgasının tarımsal üretim üzerine etkileri. Doğal Afetler ve Çevre Dergisi, 9(2), 240–257. https://doi.org/10.21324/dacd.1220462

30. Romanovska, P., Undorf, S., Schauberger, B., Duisenbekova, A., & Gornott, C. (2024). Human-induced climate change has decreased wheat production in northern Kazakhstan. https://doi.org/10.1088/2752-5295/ad53f7

31. Amirbekuly, Y., Daribayeva, A., Toxanova, A. N., et al. (2024). Эффективные методы рационального использования водных ресурсов в аграрном секторе Казахстана. Наукові горизонти.https://doi.org/10.48077/scihor12.2024.90

32. Turbekova, A., Balgabaev, N., Turbekov, S., et al. (2023). Влияние водосберегающей технологии орошения на урожайность зерновых культур в северном регионе Казахстана. Caspian Journal of Environmental Sciences.https://doi.org/10.22124/cjes.2023.7397

33. Nurlybayeva, O. (2024). Повышение эффективности использования орошаемых земель в сельском хозяйстве южного Казахстана. Environmental and Social Research. https://doi.org/10.63034/esr-89

34. Wang, D., Gao, G., Li, R., et al. (2022). Limiting factors and environmental adaptability for staple crops in Kazakhstan. Sustainability, 14(16), 9980. https://doi.org/10.3390/su14169980

35. Yagi, F., Kussainova, M., & Hoshino, B. (2022). Sustainable land management in corn farmland, southeast Kazakhstan: Report from Kazakhstan and China border. Agricultural Research Journal. https://doi.org/10.52536/2788-5909.2022-4.02

36. Suleimenova, S., & Lukáč, M. (2025). Is food secure in Central Asia: Agricultural modelling of soybean productivity and adaptation to climate change. EGUsphere. https://doi.org/10.5194/egusphere-egu25-20344