بررسی تغییرات آب مجازی محصولات زراعی در عرضهای جغرافیایی مختلف شرق کشور
محورهای موضوعی : مدیریت آب در مزرعه با هدف بهبود شاخص های مدیریتی آبیاریعلی عارفی نیا 1 , خالد احمدآلی 2
1 - دانشجوی کارشناسی ارشد منابع آب، گروه آبیاری و آبادانی، دانشگاه تهران، تهران، ایران.
2 - استادیار پردیس کشاورزی و منابع طبیعی، دانشگاه تهران، تهران، ایران.
کلید واژه: عرض جغرافیایی, نیاز آبی, آب مجازی, محصولات غالب, عملکرد محصولات زراعی,
چکیده مقاله :
دما یک عامل کلیدی در میزان عملکرد، نیازآبی و درنتیجه آب مجازی محصولات مختلف کشاورزی است. لذا بررسی اثر عرض جغرافیایی به عنوان یکی از موثرترین عوامل بر آب مجازی محصولات کشاورزی ب ضروری است. در این تحقیق محتوای آب مجازی نُه محصول عمده زراعی یعنی گندم، جو، یونجه، چغندرقند، ذرت، هندوانه، گوجه، پیاز و سیبزمینی در استانهای شرقی با استفاده از آمار 20 ساله محاسبه گردید. سپس با استفاده از نرمافزار ArcGIS، متوسط آب مجازی هریک از محصولات در عرضهای جغرافیایی از 25 تا 38 درجه شمالی به فواصل یکدرجه محاسبه شده و مورد تجزیه و تحلیل قرار گرفت. بررسی میزان همبستگی بین آب مجازی با نیازآبی و عملکرد محصولات نشان داد که میانگین آبمجازی با میانگین نیاز آبی محصولات مورد بررسی همبستگی مستقیم به اندازه 65 درصد و با میانگین عملکرد آنها 74 درصد همبستگی معکوس دارد. مقادیر میانگین آب مجازی محصولات مورد بررسی از کمترین به بیشترین عبارتست از 19/0، 38/0، 45/0، 46/0، 53/0، 57/0، 59/1، 69/1 و 80/1 هزار مترمکعب بر تن که به ترتیب مربوط محصولات ذرت، چغندرقند، پیاز، ، هندوانه، گوجه، سیبزمینی، یونجه، جو و گندم میباشد. نتایج نشان داد که الگوی تغییرات تابع آب مجازی محصولات مورد بررسی نسبت به متغیر مستقل عرض جغرافیایی در همه موارد گوسی شکل است که علیرغم مقادیر ماگزیمم متفاوت آب مجازی، این مقادیر، در بازهی مکانی 30 تا 33 درجه عرض شمالی اتفاق افتاده است و با دور شدن از بازه ذکر شده به سمت عرضهای بالاتر و یا پایینتر محتوی آب مجازی همه محصولات کاهش مییابد.
Temperature is a key factor in yield, crop water requirement, and then virtual water of various agricultural products. Therefore, it is necessary to investigate the effect of latitude as one of the most effective factors on the variation of virtual water of agricultural products. In this research, the virtual water content of nine major plants including wheat, barley, alfalfa, sugar beet, corn, watermelon, tomato, onion and potato in four eastern provinces (including 56 cities) of Iran was calculated based on 20-year statistical data. Then, the average virtual water of each plant was calculated in different latitudes from 〖25〗^° to 〖38〗^°N at 1^° intervals using ArcGIS software. The regression between the average virtual water with crop water requirement and yield of the products revealed a positive correlation between virtual water and crop water requirement (r=0.65) and a negative correlation between virtual water and yield (r= 0.74). The average virtual water from the lowest to the highest was 0.19, 0.38, 0.45, 0.46, 0.53, 0.57, 1.59, 1.69, and 1.80 thousand cubic meters per ton for corn, sugar beet, onion, watermelon, tomato, potato, alfalfa, barley, and wheat, respectively. The results showed that the variation pattern of virtual water of the studied products across different latitude was Gaussian. Despite the different maximum values of virtual water, they occurred in the latitude range of 〖30〗^° to 〖33〗^° N and by moving away from the mentioned range to higher or lower latitude, the virtual water content of all products decreases.
ناصری، ا.، عباسی، ف. و اکبری، م. 1396. برآورد آب مصرفی در بخش کشاورزی به روش بیلان آب. مجله تحقیقات مهندسی سازههای آبیاری و زهکشی، 68(18)68: 17-23.
Ababaei, B., & Etedali, H. R. 2014. Estimation of water footprint components of Iran’s wheat production: Comparison of global and national scale estimates. Environmental processes, 1(3), 193-205.
Ababaei, B., & Etedali, H. R. 2017. Water footprint assessment of main cereals in Iran. Agricultural Water Management, 179, 401-411.
Akoto-Danso, E. K., Karg, H., Drechsel, P., Nyarko, G., & Buerkert, A. 2019. Virtual water flow in food trade systems of two West African cities. Agricultural Water Management, 213, 760-772.
Akoto-Danso, E. K., Karg, H., Drechsel, P., Nyarko, G., & Buerkert, A. 2019. Virtual water flow in food trade systems of two West African cities. Agricultural Water Management, 213, 760-772.
Ali, M. H., and Mubarak, S. 2017. Effective rainfall calculation methods for field crops: An Overview, Analysis and New Formulation. Asian Research Journal of Agriculture, 1-12.
Ali, M. H., and Mubarak, S. 2017. Effective rainfall calculation methods for field crops: An Overview, Analysis and New Formulation. Asian Research Journal of Agriculture, 1-12.
Allen, R. G. 1998. Crop evapotranspiration. FAO irrigation and drainage paper, 56, 60-64.
Allen, R. G. 1998. Crop evapotranspiration. FAO irrigation and drainage paper, 56, 60-64.
Bazrafshan, O., Etedali, H. R., Moshizi, Z. G. N., & Shamili, M. 2019. Virtual water trade and water footprint accounting of Saffron production in Iran. Agricultural Water Management, 213, 368-374.
Bazrafshan, O., Etedali, H. R., Moshizi, Z. G. N., & Shamili, M. 2019. Virtual water trade and water footprint accounting of Saffron production in Iran. Agricultural Water Management, 213, 368-374.
Bulsink F, Hoekstra AY, Booij MJ, 2010. The water footprint of Indonesian provinces related to the consumption of crop products. Hydrol Earth Syst Sc 14(1): 119-128.
Bulsink F, Hoekstra AY, Booij MJ, 2010. The water footprint of Indonesian provinces related to the consumption of crop products. Hydrol Earth Syst Sc 14(1): 119-128.
Cao, X., Cui, S., Shu, R., & Wu, M. 2020. Misestimation of water saving in agricultural virtual water trade by not considering the role of irrigation. Agricultural Water Management, 241, 106355.
Cao, X., Cui, S., Shu, R., & Wu, M. 2020. Misestimation of water saving in agricultural virtual water trade by not considering the role of irrigation. Agricultural Water Management, 241, 106355.
Chapagain AK, Orr S, 2009. An improved water footprint methodology linking global consumption to local water resources: A case of Spanish tomatoes. J Environ Manage 90: 1219-1228.
Chapagain AK, Orr S, 2009. An improved water footprint methodology linking global consumption to local water resources: A case of Spanish tomatoes. J Environ Manage 90: 1219-1228.
Delpasand, M., Bozorg-Haddad, O., & Loáiciga, H. A. 2020. Integrated virtual water trade management considering self-sufficient production of strategic agricultural and industrial products. Science of The Total Environment, 140797.
Delpasand, M., Bozorg-Haddad, O., & Loáiciga, H. A. 2020. Integrated virtual water trade management considering self-sufficient production of strategic agricultural and industrial products. Science of The Total Environment, 140797.
Fader M, Gerten D, Thammer M, Heinke J, Lotze-Campen H, Lucht W, Cramer W, 2011. Internal and external greenblue agricultural water footprints of nations, and related water and land savings through trade. Hydrol Earth Syst Sc 15: 1641-1660.
Fader M, Gerten D, Thammer M, Heinke J, Lotze-Campen H, Lucht W, Cramer W, 2011. Internal and external greenblue agricultural water footprints of nations, and related water and land savings through trade. Hydrol Earth Syst Sc 15: 1641-1660.
FAO, 2005. AQUASTAT Information System on Water and Agriculture: Online database. Food and Agriculture Organization of the United Nations, Land and Water Development Division, Rome.
FAO, 2005. AQUASTAT Information System on Water and Agriculture: Online database. Food and Agriculture Organization of the United Nations, Land and Water Development Division, Rome.
FAO, 2011.Climate change, water and food security. Food and Agriculture Organization of the United Nations, Land and Water Development Division, Rome.
FAO, 2011.Climate change, water and food security. Food and Agriculture Organization of the United Nations, Land and Water Development Division, Rome.
Hoekstra AY, Chapagain AK, Aldaya MM, Mekonnen MM, 2011. The Water Footprint Assessment Manual. Earthscan, London
Hoekstra AY, Chapagain AK, Aldaya MM, Mekonnen MM, 2011. The Water Footprint Assessment Manual. Earthscan, London
Hoekstra, A. Y. 2003. Virtual water trade: A quantification of virtual water flows between nations in relation to international crop trade. In Proceedings of the International Expert Meeting on Virtual Water Trade 12, Delft, 2003 (pp. 25-47).
Hoekstra, A. Y. 2003. Virtual water trade: A quantification of virtual water flows between nations in relation to international crop trade. In Proceedings of the International Expert Meeting on Virtual Water Trade 12, Delft, 2003 (pp. 25-47).
Hoekstra, A. Y. 2009. Water security of nations: how international trade affects national water scarcity and dependency. Threats to Global Water Security, Springer, 27-36.
Hoekstra, A. Y. 2009. Water security of nations: how international trade affects national water scarcity and dependency. Threats to Global Water Security, Springer, 27-36.
Hoekstra, A. Y., and Hung, P. Q. 2005 "Virtual water trade." Proc., Proceedings of the international expert meeting on virtual water trade, 1-244.
Hoekstra, A. Y., and Hung, P. Q. 2005 "Virtual water trade." Proc., Proceedings of the international expert meeting on virtual water trade, 1-244.
Liu J, Yang H, 2010. Spatially explicit assessment of global consumptive water uses in cropland: green and blue water. J Hydrol 384: 187-197.
Liu J, Yang H, 2010. Spatially explicit assessment of global consumptive water uses in cropland: green and blue water. J Hydrol 384: 187-197.
Liu, X., Shi, L., Engel, B. A., Sun, S., Zhao, X., Wu, P., & Wang, Y. 2020. New challenges of food security in Northwest China: Water footprint and virtual water perspective. Journal of Cleaner Production, 245, 118939.
Long AH, Xu ZM, Zhang ZQ, Su ZY, 2005. Primary estimation of water footprint of Gansu Province in 2000. Resour Sci 27: 123-129.
Long AH, Xu ZM, Zhang ZQ, Su ZY, 2005. Primary estimation of water footprint of Gansu Province in 2000. Resour Sci 27: 123-129.
Lowry, W. P. 1972. Compendium of lecture notes in climatology for Class III meteorological personnel, Secretariat of the World Meteorological Organization.
Lowry, W. P. 1972. Compendium of lecture notes in climatology for Class III meteorological personnel, Secretariat of the World Meteorological Organization.
Ma J, Wang DX, Lai HL, Wang Y, 2005. Water footprint-An application in water resources research. Resour Sci 27: 96-100.
Ma J, Wang DX, Lai HL, Wang Y, 2005. Water footprint-An application in water resources research. Resour Sci 27: 96-100.
Maeda EE, Pellikka K, Clark BJ, Siljander M, 2011. Prospective changes in irrigation water requirements caused by agricultural expansion and climate changes in the eastern arc mountains of Kenya. J Environ Manage 92: 982-993.
Maeda EE, Pellikka K, Clark BJ, Siljander M, 2011. Prospective changes in irrigation water requirements caused by agricultural expansion and climate changes in the eastern arc mountains of Kenya. J Environ Manage 92: 982-993.
Mekonnen MM, Hoekstra AY, 2010. The green, blue and grey water footprint of crops and derived crop products. Value of Water Research Report Series No. 47, UNESCOIHE, Delft, The Netherlands. Available in http://www. waterfootprint.org/Reports/ Report47WaterFootprintCropsVol1.pdf.
Mekonnen MM, Hoekstra AY, 2010. The green, blue and grey water footprint of crops and derived crop products. Value of Water Research Report Series No. 47, UNESCOIHE, Delft, The Netherlands. Available in http://www. waterfootprint.org/Reports/ Report47WaterFootprintCropsVol1.pdf.
Schwarz, J., Mathijs, E., & Maertens, M. 2019. A dynamic view on agricultural trade patterns and virtual water flows in Peru. Science of The Total Environment, 683, 719-728.
Schwarz, J., Mathijs, E., & Maertens, M. 2019. A dynamic view on agricultural trade patterns and virtual water flows in Peru. Science of The Total Environment, 683, 719-728.
Sun, S. K., Yin, Y. L., Wu, P. T., Wang, Y. B., Luan, X. B., & Li, C. 2019. Geographical evolution of agricultural production in China and its effects on water stress, economy, and the environment: the virtual water perspective. Water Resources Research, 55(5), 4014-4029.
Talozi, S., Al Sakaji, Y., & Altz-Stamm, A. 2020. Towards a water–energy–food nexus policy: realizing the blue and green virtual water of agriculture in Jordan. International Journal of Water Resources Development, 31(3), 461-482.
Xiong W, Holman I, Lin ED, Conway D, Jiang JH, Xu YL, Li Y, 2010. Climate change, water availability and future cereal production in China. Agr Ecosyst Environ 135: 58–69.
Xiong W, Holman I, Lin ED, Conway D, Jiang JH, Xu YL, Li Y, 2010. Climate change, water availability and future cereal production in China. Agr Ecosyst Environ 135: 58–69.
Ye, Q., Li, Y., Zhuo, L., Zhang, W., Xiong, W., Wang, C., & Wang, P. 2018. Optimal allocation of physical water resources integrated with virtual water trade in water scarce regions: a case study for Beijing, China. water research, 129, 264-276.
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