Development of irrigated agriculture in Uzbekistan and its impact on ecological environment and economic development
Received date: 2020-12-29
Revised date: 2021-04-14
Online published: 2021-12-03
In this paper, the latest relevant data of Uzbekistan were obtained from the databases of the Food and Agriculture Organization of the United Nations and the United Nations data retrieval system. The development history of irrigated agriculture was investigated by analyzing the data on irrigated areas and the population and economic development in the country, and a series of environmental problems caused by unreasonable irrigation and their impact on the social economy were discussed. The results demonstrated that as Uzbekistan is a typical agricultural country, its irrigated agriculture has been developing steadily, supporting the food security and employment of the entire country. The agricultural irrigation area of Uzbekistan increased to 4.2×106 hm2 in the 1990s and remained basically unchanged over the following 30 years. The main water sources for agricultural irrigation are the Amu Darya and Syr Darya rivers, and most irrigation methods are based on flood irrigation. Because of the dry climate with limited rainfall, long-term irrigation has led to a continuous decline of river flow and water storage in the Aral Sea. To cope with sluggish economic growth and food demand, increasing amounts of farmland were shifted from producing cotton to wheat in the 1990s, as wheat requires less water. However, the gradual phase-out of cotton exports in Uzbekistan and the conversion of its farmland from food to fruits and vegetables, done to transform its economic structure from over-reliance on agricultural production to a more economically rewarding system within the limited land, led to a sharp decline in wheat and cotton production in 2016. Additionally, the long-term use of relatively backward water supply systems and irrigation technology has caused a serious waste of water resources and a series of environmental problems. The flooding irrigation method coupled with strong evaporation and declining irrigation water quality along with the higher groundwater level has caused large-scale salinization of soil and made Uzbekistan the sixth largest country in terms of soil salinization, with a total of 2.1×106 hm2 of salinized soil. The area of the Aral Sea also shrunk from 4.7×106-4.8×106 to 1.2×106 hm2 over the past 40 years, and the sea could vanish within the next 40 years, resulting in a significant reduction in water storage and a three-fold increase in salinity compared with 20 years ago. The drying up of the Aral Sea also exposed a large area of salty sediments and finally formed a new desert (the Aralkum) in 2000, causing frequent salt dust storms, which pose a serious threat to human respiratory health and the hydrological cycle. Agricultural production is economically important in Uzbekistan. It has a significant positive impact on gross domestic product and can effectively the effects of small fluctuations in the industrial and service sectors. Still, the problem of soil salinization in Uzbekistan is extremely complex. To effectively address the issue, it is necessary to fundamentally optimize the irrigation mode and drainage technology and implement advanced and efficient irrigation and drainage schemes, such as drip irrigation, sprinkler irrigation, and subsurface pipe network salt drainage. This study offers support for agricultural development and water resource management in arid areas.
Key words: irrigation; arid land; agriculture; cotton; wheat; Uzbekistan; Central Asia
LI Qi,LI Fadong,WANG Guoqin,QIAO Yunfeng,Rashid KULMATOV,PENG Yu,Sayidjakhon KHASANOV,LIU Hongguang,HE Xinlin,YANG Guang . Development of irrigated agriculture in Uzbekistan and its impact on ecological environment and economic development[J]. Arid Land Geography, 2021 , 44(6) : 1810 -1820 . DOI: 10.12118/j.issn.1000–6060.2021.06.28
| [1] | Tilman D, Balzer C, Hill J, et al. Global food demand and the sustainable intensification of agriculture[J]. Proceedings of the National Academy of Sciences of the United States of America, 2011, 108(50):20260-20264. |
| [2] | Mueller N D, Gerber J S, Johnston M, et al. Closing yield gaps through nutrient and water management[J]. Nature, 2012, 490(7419):254-257. |
| [3] | 王新源, 赵学勇, 李玉霖, 等. 环境因素对干旱半干旱区凋落物分解的影响研究进展[J]. 应用生态学报, 2013, 24(11):3300-3310. |
| [3] | [ Wang Xinyuan, Zhao Xueyong, Li Yulin, et al. Effects of environmental factors on litter decomposition in arid and semi-arid regions: A review[J]. Chinese Journal of Applied Ecology, 2013, 24(11):3300-3310. ] |
| [4] | Huang J, Yu H, Guan X, et al. Accelerated dryland expansion under climate change[J]. Nature Climate Change, 2016, 6(2):166-171. |
| [5] | Deng H, Chen Y. Influences of recent climate change and human activities on water storage variations in Central Asia[J]. Journal of Hydrology, 2017, 544:46-57. |
| [6] | 郝海超, 郝兴明, 花顶, 等. 2000—2018年中亚五国水分利用效率对气候变化的响应[J]. 干旱区地理, 2021, 44(1):1-14. |
| [6] | [ Hao Haichao, Hao Xingming, Hua Ding, et al. Response of water use efficiency to climate change in five Central Asian countries from 2000 to 2018[J]. Arid Land Geography, 2021, 44(1):1-14. ] |
| [7] | Lioubimtseva E, Henebry C M. Climate and environmental change in arid Central Asia: Impacts, vulnerability, and adaptations[J]. Journal of Arid Environments, 2009, 73(11):963-977. |
| [8] | Xu B R, Lu Z X, S Y. Glacier changes and their impacts on the discharge in the past half-century in Tekes watershed, Central Asia[J]. Physics and Chemistry of the Earth, 2015, 89-90:96-103. |
| [9] | Abdullaev I D, Fraiture C, Giordano M, et al. Agricultural water use and trade in Uzbekistan: Situation and potential impacts of market liberalization[J]. International Journal of Water Resources Development, 2009, 25(1):47-63. |
| [10] | 马大正, 冯锡时. 中亚五国史纲[M]. 乌鲁木齐: 新疆人民出版社, 2000: 266-273. |
| [10] | [ Ma Dazheng, Feng Xishi. Outline of the history of the five countries in Central Asia[M]. Urumqi: Xinjiang People’s Publishing House, 2000: 266-273. ] |
| [11] | Ibrakhimov M, Martius C, Lamers J P A, et al. The dynamics of groundwater table and salinity over 17 years in Khorezm[J]. Agricultural Water Management, 2011, 101(1):52-61. |
| [12] | Mateo S J, Marjani S, Turral H. More people, more food, worse water? A global review of water pollution from agriculture[M]. Rome: Food and Agriculture Organization of the United Nations, 2018: 93-105. |
| [13] | Crosa G, Froebrich J, Nikolayenko V, et al. Spatial and seasonal variations in the water quality of the Amu Darya River (Central Asia)[J]. Water Research, 2006, 40(11):2237-2245. |
| [14] | Jacques C, Peter O, Philip M. Dying and Dead Seas climatic versus anthropic causes[M]. Dordecht: Springer Netherlands, 2004: 34-41. |
| [15] | 梁倩, 光莹, 刘琼, 等. 新疆及周边中亚地区中亚低涡背景下云中液态水分布研究[J]. 干旱区地理, 2020, 43(1):72-78. |
| [15] | [ Liang Qian, Guang Ying, Liu Qiong, et al. Distribution of total cloud liquid water in Xinjiang and its surrounding Central Asia under the background of low vortex in Central Asia[J]. Arid Land Geography, 2020, 43(1):72-78. ] |
| [16] | Groll M, Opp C, Kulmatov R, et al. Water quality, potential conflicts and solutions: An upstream-downstream analysis of the transnational Zarafshan River (Tajikistan, Uzbekistan)[J]. Environmental Earth Sciences, 2015, 73(2):743-763. |
| [17] | Egamberdieva D, Kamilova F, Validov S, et al. High incidence of plant growth-stimulating bacteria associated with the rhizosphere of wheat grown on salinated soil in Uzbekistan[J]. Environmental Microbiology, 2008, 10(1):1-9. |
| [18] | 王旋旋, 陈亚宁, 李稚, 等. 基于模糊综合评价模型的中亚水资源开发潜力评估[J]. 干旱区地理, 2020, 43(1):126-134. |
| [18] | [ Wang Xuanxuan, Chen Yaning, Li Zhi, et al. Assessment of the development potential of water resources in Central Asia based on fuzzy comprehensive evaluation model[J]. Arid Land Geography, 2020, 43(1):126-134. ] |
| [19] | Kulmatov R, Mirzaev J, Abuduwaili J, et al. Challenges for the sustainable use of water and land resources under a changing climate and increasing salinization in the Jizzakh irrigation zone of Uzbekistan[J]. Journal of Arid Land, 2020, 12(1):90-103. |
| [20] | Lerman Z. Agricultural development in Uzbekistan: The effect of ongoing reforms[R]. Israel: Hebrew University of Jerusalem, Department of Agricultural Economics and Management, 2008. |
| [21] | Food and Agriculture Organization of the United Nations. FAO’s Global Information System on Water and Agriculture[DB/OL]. [2020-05-18]. http://www.fao.org/nr/water/Aquastat/countries_regions/Profile_segments/UZB-IrrDr_eng.stm . |
| [22] | Lerman Z. Agricultural development in Central Asia: A survey of Uzbekistan, 2007—2008[J]. Eurasian Geography and Economics, 2008, 49(4):481-505. |
| [23] | 胡汝骥, 陈曦, 姜逢清, 等. 人类活动对亚洲中部水环境安全的威胁[J]. 干旱区研究, 2011, 28(2):189-197. |
| [23] | [ Hu Ruji, Chen Xi, Jiang Fengqing, et al. Threat of human activities to hydrological regime in Central Asia[J]. Arid Zone Research, 2011, 28(2):189-197. ] |
| [24] | Ruan H W, Yu J J, Wang P, et al. Increased crop water requirements have exacerbated water stress in the arid transboundary rivers of Central Asia[J]. Science of the Total Environment, 2020, 713:136585, doi: 10.1016/j.scitotenv.2020.136585. |
| [25] | 阮宏威, 于静洁. 1992—2015年中亚五国土地覆盖与蒸散发变化[J]. 地理学报, 2019, 74(7):1292-1304. |
| [25] | [ Ruan Hongwei, Yu Jingjie. Changes in land cover and evapotranspiration in the five Central Asian countries from 1992 to 2015[J]. Acta Geographica Sinica, 2019, 74(7):1292-1304. ] |
| [26] | Djanibekov N, Sommer R, Djanibekov U. Evaluation of effects of cotton policy changes on land and water use in Uzbekistan: Application of a bio-economic farm model at the level of a water users association[J]. Agricultural Systems, 2013, 118:1-13. |
| [27] | Conrad C, Rahmann M, Machwitz M, et al. Satellite based calculation of spatially distributed crop water requirements for cotton and wheat cultivation in Fergana Valley, Uzbekistan[J]. Global and Planetary Change, 2013, 110:88-98. |
| [28] | Lee S O, Jung Y. Efficiency of water use and its implications for a water-food nexus in the Aral Sea Basin[J]. Agricultural Water Management, 2018, 207:80-90. |
| [29] | 徐婷, 邵华, 张弛. 近32 a中亚地区气温时空格局分析[J]. 干旱区地理, 2015, 38(1):25-35. |
| [29] | [ Xu Ting, Shao Hua, Zhang Chi. Temporal pattern analysis of air temperature change in Central Asia during 1980—2011[J]. Arid Land Geography, 2015, 38(1):25-35. ] |
| [30] | Kulmatov R, Groll M, Rasulov A, et al. Status quo and present challenges of the sustainable use and management of water and land resources in Central Asian irrigation zones: The example of the Navoi region (Uzbekistan)[J]. Quaternary International, 2018, 464:396-410. |
| [31] | Rakhimbaev F, Bezpalov M, Khamidov M, et al. Peculiarities of crop irrigation in lower Amu Darya River areas[M]. Tashkent, Uzbekistan: FAN, 1992: 34-58. |
| [32] | Mirzakhayot I, Asia K, Irina F, et al. Groundwater table and salinity: Spatial and temporal distribution and influence on soil salinization in Khorezm region (Uzbekistan, Aral Sea Basin)[J]. Irrigation Drainage Systems, 2007, 21(3-4):219-236. |
| [33] | Kulmatov R, Rasulov A, Kulmatova D, et al. The modern problems of sustainable use and management of irrigated lands on the example of the Bukhara region (Uzbekistan)[J]. College Composition & Communication, 2015, 7(12):956-971. |
| [34] | 吴敬禄, 马龙, 吉力力·阿不都外力. 中亚干旱区咸海的湖面变化及其环境效应[J]. 干旱区地理, 2009, 32(3):418-422. |
| [34] | [ Wu Jinglu, Ma Long, Abuduwaili Gilili. Lake surface change of the Aral Sea and its environmental effects in the arid region of the Central Asia[J]. Arid Land Geography, 2009, 32(3):418-422. ] |
| [35] | McKinney D C. Cooperative management of transboundary water resources in Central Asia[M]. Washington D.C.: National Defense University Press, 2004: 187-220. |
| [36] | Cretaux J F, Letolle R, Berge-Nguyen M. History of Aral Sea level variability and current scientific debates[J]. Global and Planetary Change, 2013, 110:99-113. |
| [37] | Glantz M H. Aral Sea Basin: A sea dies, a sea also rises[J]. Ambio, 2007, 36(4):323-327. |
| [38] | Gaybullaev B, Chen S C, Gaybullaev G. The large Aral Sea water balance: A future prospective of the large Aral Sea depending on water volume alteration[J]. Carbonates and Evaporites, 2014, 29(2):211-219. |
| [39] | Jin L Y, Chen F H, Carrie M, et al. Causes of early Holocene desertification in arid Central Asia[J]. Climate Dynamics, 2012, 38(7):1577-1591. |
| [40] | Dubovyk O, Menz G, Conrad C, et al. Spatio-temporal analyses of cropland degradation in the irrigated lowlands of Uzbekistan using remote-sensing and logistic regression modeling[J]. Environmental Monitoring Assessment, 2013, 185(6):4775-4790. |
| [41] | Christopher C, Bjrn O K, John P A. Quantifying water volumes of small lakes in the inner Aral Sea Basin, Central Asia, and their potential for reaching water and food security[J]. Environmental Earth Sciences, 2016, 75(11):1-16. |
| [42] | Zhang F, Tashpolat T, Verner C J, et al. The influence of natural and human factors in the shrinking of the Ebinur Lake, Xinjiang, China, during the 1972—2013 period[J]. Environmental Monitoring and Assessment, 2014. 187(1):4128. doi: 10.1007/s10661-014-4128-4. |
| [43] | Orlovsky N, Orlovsky L, 杨有林, 等. 20世纪60年代以来中亚地区的盐尘暴[J]. 中国沙漠, 2003, 23(1):20-29. |
| [43] | [ Orlovsky N, Orlovsky L, Yang Youlin, et al. Salt duststorms of Central Asia since 1960s[J]. Journal of Desert Research, 2003, 23(1):20-29. ] |
| [44] | Gill T E. Eolian sediments generated by anthropogenic disturbance of playas: Human impacts on the geomorphic system and geomorphic impacts on the human system[J]. Geomorphology, 1996, 17(1-3):207-228. |
| [45] | 刘金平, 包安明, 李均力, 等. 2001—2013年中亚干旱区季节性积雪监测及时空变异分析[J]. 干旱区地理, 2016, 39(2):405-412. |
| [45] | [ Liu Jinping, Bao Anming, Li Junli, et al. Spatial and temporal characteristics of snow cover in arid area of Central Asia from 2001 to 2013[J]. Arid Land Geography, 2016, 39(2):405-412. ] |
| [46] | 吉力力·阿不都外力 木巴热克·阿尤普 刘东伟, 等. 中亚五国水土资源开发及其安全性对比分析[J]. 冰川冻土, 2009, 31(5):960-968. |
| [46] | [ Abuduwaili Gilili, Ayoupu Mubarek, Liu Dongwei, et al. Comparative analysis of the land-water resources exploitation and its safety in the five countries of Central Asia[J]. Journal of Glaciology and Geocryology, 2009, 31(5):960-968. ] |
| [47] | Kulmatov R. Problems of sustainable use and management of water and land resources in Uzbekistan[J]. Journal of Water Resource and Protection, 2014, 6(1):35-42. |
| [48] | Orlovsky L G, Tolkacheva N O, et al. Dust storms as a factor of atmospheric air pollution in the Aral Sea Basin[J]. Air Pollution XII, 2004, 74:353-362. |
| [49] | Issanova G, Abuduwaili J. Aeolian processes as dust storms in the deserts of Central Asia[M]. Singapore: Springer Nature, 2017: 52-63. |
| [50] | Lerman Z. Land reform, farm structure, and agricultural performance in CIS countries[J]. China Economic Review, 2009, 20(2):316-326. |
| [51] | 肖金波, 曲昊月. 乌兹别克斯坦农业经济改革及发展成效[J]. 安徽工业大学学报(社会科学版), 2018, 35(4):30-33, 35. |
| [51] | [ Xiao Jinbo, Qu Haoyue. Agricultural economy reform and development effectiveness in Uzbekistan[J]. Journal of Anhui University of Technology (Social Sciences Edition), 2018, 35(4):30-33, 35. ] |
| [52] | Bobojonov I, Franz J, Berg E, et al. Improved policy making for sustainable farming: A case study on irrigated dryland agriculture in western Uzbekistan[J]. Journal of Sustainable Agriculture, 2010, 34(7):800-817. |
| [53] | Opp C, Groll M, Aslanov I, et al. Aeolian dust deposition in the southern Aral Sea region (Uzbekistan): Ground-based monitoring results from the LUCA project[J]. Quaternary International, 2017, 429:86-99. |
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