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Bulletin of the Kyrgyz National Agrarian University

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Potential for apricot farming and processing in Central Asia

M Meerim Tynarbekova J Jamila Smanalieva T Thomas Henle
Received 03.10.2025
Revised 12.02.2026
Published 10.03.2026

Abstract

Apricot (Prunus armeniaca L.) remains one of the key fruits of temperate zones, with Central Asia serving as a major centre of its origin and genetic diversity. The study aimed to evaluate the economic potential of fresh and dried apricot production and trade worldwide, with a special focus on Central Asian countries, and to assess the efficiency of various drying technologies. Data from FAOSTAT, WITS, Tridge and WTO for 2020-2025, along with a systematic review of scientific literature on drying technologies (Scopus, Web of Science, etc.), were used; return on investment (ROI) and gross profit were calculated for traditional sun drying, convective, infrared and freeze-drying methods assuming an annual output of 50 tonnes of dried apricots. It was established that global apricot production reached approximately 4.5 million tonnes in 2024; Turkey, Uzbekistan and Iran remain the leading producers, but in 2025 catastrophic spring frosts in Turkey (particularly in Malatya province) reduced output, causing a sharp rise in global prices for fresh and dried apricots. In Central Asia, Uzbekistan (~526-540 thousand tonnes in 2024), Tajikistan (~313-348 thousand tonnes in 2024-2025) and Kyrgyzstan (~57 thousand tonnes in 2023-2024) demonstrate substantial export potential; Turkey exported dried apricots worth USD 404.5 million in 2024, yet regional suppliers (especially Uzbekistan and Tajikistan) gain competitive advantages in 2025. ROI calculations showed: sun drying – 7.3%, convective – 23.4%, infrared – 28.5%, freeze-drying – 33.9%; infrared and freeze-drying provide the highest product quality. The findings can be applied by farmers, processors and investors in Central Asia (primarily Kyrgyzstan) to select appropriate drying technologies, reduce post-harvest losses and access premium export markets (EU, USA, Russia)

Keywords

harvested area; yield; drying technology; equipment; return on investment; operating costs
Suggested citation
Tynarbekova, M., Smanalieva, J., & Henle, T. (2026). Potential for apricot farming and processing in Central Asia. Bulletin of the Kyrgyz National Agrarian University, 24(1), 63-76. https://doi.org/10.63621/bknau./1.2026.63

References

  1. Adak, N., Heybeli, N., & Ertekin, C. (2017). Infrared drying of strawberry. Food Chemistry, 219, 109-116. doi: 10.1016/j.foodchem.2016.09.103.
  2. Adeyeye, S.A.O., Ashaolu, T.J., & Babu, A.S. (2022). Food drying: A review. Agricultural Reviews, 1(8), 1-8. doi: 10.18805/ag.R-2537.
  3. Ahmed, A., Raza, A., Khalid, N., Malik, A.M., Asghar, M., & Abid, H.M.R. (2020). Development of apricot (Prunus armeniaca L.) powder and its food application. Journal of Pure and Applied Agriculture, 5(2), 26-33.
  4. Akter, F., Muhury, R., Sultana, A., & Deb, U.K. (2022). A comprehensive review of mathematical modeling for drying processes of fruits and vegetables. International Journal of Food Science, 2022, article number 6195257. doi: 10.1155/2022/6195257.
  5. Al-Soufi, M.H., et al. (2022). A review with updated perspectives on nutritional and therapeutic benefits of apricot and the industrial application of its underutilized parts. Molecules, 27(15), article number 5016. doi: 10.3390/molecules27155016.
  6. Arslan, A., & Alibaş, İ. (2024). Assessing the effects of different drying methods and minimal processing on the sustainability of the organic food quality. Innovative Food Science & Emerging Technologies, 94, article number 103681. doi: 10.1016/j.ifset.2024.103681.
  7. Asia-Plus. (2025). Tajikistan’s fruit production exceeds expectations. Retrieved from.https://asiaplustj.info/en/news/tajikistan/economic/20251226/tajikistans-fruit-production-surpasses-expectations.
  8. Azarov, A., Maurer, M.K., Weyerhaeuser, H., & Darr, D. (2019). The impact of uncertainty on smallholder farmers’ income in Kyrgyzstan. Journal of Agriculture and Rural Development in the Tropics and Subtropics, 120(2), 183-195. doi: 10.17170/kobra-20191127816.
  9. Bhatta, S., Stevanovic Janezic, T., & Ratti, C. (2020). Freeze-drying of plant-based foods. Foods, 9(1), article number 87. doi: 10.3390/foods9010087.
  10. CentralAsia. (2017). Life in Central Asia: Dried fruit production from the famous Asht apricots (photo report). Retrieved from https://centralasia.media/print:1397055.
  11. EastFruit. (2020). Who ate the Tajik apricot, or why is the area of ​​orchards growing while the export of dried apricots and dried fruit is rapidly declining? Retrieved from https://east-fruit.com/novosti/kto-sel-tadzhikskiy-abrikos-ili-pochemu-ploshchad-sadov-rastet-a-eksport-kuragi-i-sukhofruktov-bystro-padaet/.
  12. EastFruit. (2022a). Gardeners in Uzbekistan continue to harvest and export apricots. Retrieved from https://east-fruit.com/novosti/sadovody-uzbekistana-prodolzhayut-sbor-i-eksport-abrikosov/.
  13. EastFruit. (2022b). Uzbekistan: New apricot harvest exports have begun from southern regions. Retrieved from https://east-fruit.com/novosti/uzbekistan-iz-yuzhnykh-regionov-nachalsya-eksport-abrikosa-novogo-urozhaya-foto/.
  14. EastFruit. (2023). Apricot of Tajikistan: Harvest pleases, prices disappoint. Retrieved from https://east-fruit.com/en/news/apricot-of-tajikistan-harvest-pleases-prices-disappoint-photo/.
  15. Elmaci, Y., Altug, T., & Pazir, F. (2008). Quality changes in unsulfured sun dried apricots during storage. International Journal of Food Properties, 11(1), 146-157. doi: 10.1080/10942910701279945.
  16. El-Mesery, H.S., Ashiagbor, K., Hu, Z., & Alshaer, W.G. (2023). A novel infrared drying technique for processing of apple slices: Drying characteristics and quality attributes. Case Studies in Thermal Engineering, 52, article number 103676. doi: 10.1016/j.csite.2023.103676.
  17. Ergashova, M.A. (2018). Genetic fund of apricots and prospects of its use in Tajikistan. Pomiculture & Small Fruits Culture in Russia, 54, 200-204. doi: 10.31676/2073-4948-2018-54-200-204.
  18. Ertekin, C., Aktas, T., Alibas, I., & Essalhi, H. (2023). Drying of fruits and vegetables. In S.M. Jafari & N. Malekjani (Eds.), Drying technology in food processing: Unit operations and processing equipment in the food industry (pp. 491-542). Amsterdam: Elsevier. doi: 10.1016/B978-0-12-819895-7.00004-3.
  19. Expana. (2025). Apricot market: Severe Türkiye frost slashes output, sends global prices soaring. Retrieved from https://www.expanamarkets.com/insights/article/apricot-market-severe-turkiye-frost-slashes-output-sends-global-prices-soaring/#:~:text=T%C3%BCrkiye%20exported%20$475%20million%20in%20apricots%20in,from%20countries%20like%20Uzbekistan%2C%20Spain%2C%20and%20Italy.
  20. FAOSTAT. (n.d.). Crops and livestock products. Retrieved from https://www.fao.org/faostat/en/#data/QCL/visualize.
  21. Fruit and Vegetable Dryer. (2025). Retrieved from https://hnybjixie.en.made-in-china.com/product/jmlpUqMGuTra/China-Fruit-and-Vegetable-Dryer-Hot-Air-Dryer-for-Fruit-and-Vegetable-Apricot-Dryer.html.
  22. Gao, J.-R., Li, M.-Y., Cheng, Z.-Y., Liu, X.-Y., Yang, H., Li, M.-T., He, R.-Y., Zhang, Q., & Yang, X.-H. (2024). Effects of different drying methods on drying characteristics and quality of small white apricot (Prunus armeniaca L.). Agriculture, 14(10), article number 1716. doi: 10.3390/agriculture14101716.
  23. Güçlü, K., Altun, M., Özyürek, M., Karademir, S.E., & Apak, R. (2006). Antioxidant capacity of fresh, sun- and sulphited-dried Malatya apricot (Prunus armeniaca) assayed by CUPRAC, ABTS/TEAC and folin methods. International Journal of Food Science and Technology, 41(S1), 76-85. doi: 10.1111/j.1365-2621.2006.01347.x.
  24. Hussain, A., Ishfaq Akbar, P., & Lamo, K. (2012). Apricot drying: Preservation technique currently practiced in Ladakh, India. Stewart Postharvest Review, 8(3), 1-6. doi: 10.2212/spr.2012.3.1.
  25. Igual, M., García-Martínez, E., Martín-Esparza, M.E., & Martínez-Navarrete, N. (2012). Effect of processing on the drying kinetics and functional value of dried apricot. Food Research International, 47(2), 284-290. doi: 10.1016/j.foodres.2011.07.019.
  26. Kadyrov, A.A. (2023). Final report on the comprehensive assessment of the economic situation and competitiveness of agribusiness with the aim of building a value chain and productive partnerships in the Batken region. Retrieved from https://www.batken.gov.kg/file/page/8_finalnyi-otchet_070823.pdf
  27. Karabulut, I., Topcu, A., Duran, A., Turan, S., & Ozturk, B. (2007). Effect of hot air drying and sun drying on color values and β-carotene content of apricot (Prunus armenica L.). LWT – Food Science and Technology, 40(5), 753-758. doi: 10.1016/j.lwt.2006.05.001.
  28. Karataş, N., & Şengül, M. (2020). Some important physicochemical and bioactive characteristics of the main apricot cultivars from Turkey. Turkish Journal of Agriculture and Forestry, 44(6), 651-661. doi: 10.3906/tar-2002-95.
  29. Kayran, S., & Doymaz, İ. (2021). Drying of Cataloglu apricots: The effect of sodium metabisulfite solution on drying kinetics, diffusion coefficient, and color parameters. International Journal of Fruit Science, 21(1), 270-283. doi: 10.1080/15538362.2021.1873218.
  30. KEMOLO. (n.d.). FD-1000 food freeze dryer. Retrieved from https://www.liofilizador.com/products/food_freeze_dryer.html.
  31. Kiralan, M., Özkan, G., Kucukoner, E., & Ozcelik, M.M. (2019). Apricot (Prunus armeniaca L.) oil. In M.F. Ramadan (Ed.), Fruit oils: Chemistry and functionality (pp. 505-519). Cham: Springer. doi: 10.1007/978-3-030-12473-1_25.
  32. Mirzabaev, A., Strokov, A., & Krasilnikov, P. (2023). The impact of land degradation on agricultural profits and implications for poverty reduction in Central Asia. Land Use Policy, 126, article number 106530. doi: 10.1016/j.landusepol.2022.106530.
  33. Mirzaeva, M.A., & Makhmudova, M.A. (2020). Drying technology of apricot varieties suitable for drying. Universum: Technical Sciences: Electronic. Scientific Journal, 12(81).
  34. Murzakulova, A. (2024). The power of apricot: Border disputes, land scarcity and mobility in the Isfara River Basin. In J. Feaux de la Croix & B. Penati (Eds.), Environmental humanities in Central Asia (pp. 245-261). Milton Park: Taylor & Francis. doi: 10.4324/9781003362364-16.
  35. Nowak, D., & Jakubczyk, E. (2020). The freeze-drying of foods – the characteristic of the process course and the effect of its parameters on the physical properties of food materials. Foods, 9(10), article number 1488. doi: 10.3390/foods9101488.
  36. OEC. (n.d.). Retrieved from https://oec.world/en.
  37. Polat, A.A., & Caliskan, O. (2013). Yield and fruit characteristics of various apricot cultivars under subtropical climate conditions of the Mediterranean Region in Turkey. International Journal of Agronomy, 2013(1), article number 687345. doi: 10.1155/2013/687345.
  38. Poyraz, S., & Gül, M. (2022). The development of apricot production and foreign trade in the world and in Turkey. Scientific Papers Series Management, Economic Engineering in Agriculture and Rural Development, 22(2), 601-616.
  39. Programme for the Development of the Food and Processing Industry of the Kyrgyz Republic for 2017-2021. (2017, March). Retrieved from https://cbd.minjust.gov.kg/53-290/edition/851186/ru.
  40. Qureshi, T.A. (2022). Identifying the potential of horticulture exports to China from Pakistan, Tajikistan, Kyrgyzstan, and Uzbekistan. Urumqi: CAREC Institute.
  41. Ratti, C. (2001). Hot air and freeze-drying of high-value foods: A review. Journal of Food Engineering, 49(4), 311-319. doi: 10.1016/S0260-8774(00)00228-4.
  42. Su, F., Liu, Y., Chen, L., Orozbaev, R., & Tan, L. (2024). Impact of climate change on food security in the Central Asian countries. Science China Earth Sciences, 67, 268-280. doi: 10.1007/s11430-022-1198-4.
  43. TAJSTAT. (n.d.). Retrieved from https://www.stat.tj/en/.
  44. Toğrul, İ.T. (2005). Convective heat transfer coefficient of apricots under open sun drying conditions. Chemical Engineering Communications, 192(8), 1036-1045. doi: 10.1080/009864490522579.
  45. Toğrul, İ.T., & Pehlivan, D. (2003). Modelling of drying kinetics of single apricot. Journal of Food Engineering, 58(1), 23-32. doi: 10.1016/S0260-8774(02)00329-1.
  46. Tridge. (n.d.). Retrieved from https://www.tridge.com/about/data-analytics/trade?next=%252Ftrades.
  47. Tynarbekova, M., Smanalieva, J., Novoslavskij, A., Liaudanskas, M., Žvikas, V., Jakštas, V., & Henle, T. (2025). Effects of pre-treatment methods on the physical properties, phenolic composition, antioxidant capacity in vitro, and microbiological safety indicators of dried apricot (Prunus armeniaca L.). Journal of Food Measurement and Characterization, 19, 9976-9986. doi: 10.1007/s11694-025-03588-w.
  48. U.S. Department of Agriculture. (2022). Prune, dried. Retrieved from https://fdc.nal.usda.gov/food-details/2344706/nutrients.
  49. UNECE. (2017). UNECE standard FFV-02 concerning the marketing and commercial quality control of apricots. Geneva: United Nations Economic Commission for Europe.
  50. Vijayavenkataraman, S., Iniyan, S., & Goic, R. (2012). A review of solar drying technologies. Renewable and Sustainable Energy Reviews, 16(5), 2652-2670. doi: 10.1016/j.rser.2012.01.007.
  51. World Integrated Trade Solution (WITS). (2024). Dried apricots exports by country in 2024. Retrieved from https://wits.worldbank.org/trade/comtrade/en/country/ALL/year/2024/tradeflow/Exports/partner/WLD/product/081310#:~:text=in%202024,imports%20by%20country%20in%202024.
  52. World Trade Organization (WTO). (n.d.). Retrieved from https://www.wto.org/.
  53. Ye, L., EL-Mesery, H.S., Ashfaq, M.M., Shi, Y., Zicheng, H., & Alshaer, W.G. (2021). Analysis of energy and specific energy requirements in various drying process of mint leaves. Case Studies in Thermal Engineering, 26, article number 101113. doi: 10.1016/j.csite.2021.101113.
  54. Zhang, D., Huang, D., Zhang, Y., Lu, Y., Huang, S., Gong, G., & Li, L. (2023). Ultrasonic assisted far infrared drying characteristics and energy consumption of ginger slices. Ultrasonics Sonochemistry, 92, article number 106287. doi: 10.1016/j.ultsonch.2022.106287.
  55. Zhang, Y., Li, T., Hu, Q., He, L., & Li, X. (2025). Food security changes in Central Asia during 1992-2019 and potential assessment in different scenarios based on self-sufficiency. Environmental Impact Assessment Review, 114, article number 107900. doi: 10.1016/j.eiar.2025.107900.