شناخت و تحلیل ظرفیت های منابع آب سطحی، پیش نیاز برنامه ریزی آمایش سرزمین در استان کرمان

کاظمی, رحیم; پرهمت, جهانگیر; شریفی, فرود

doi:10.22092/wmej.2019.126446.1222

شناخت و تحلیل ظرفیت های منابع آب سطحی، پیش نیاز برنامه ریزی آمایش سرزمین در استان کرمان

نوع مقاله : پژوهشی

نویسندگان

¹ استادیار پژوهشکده حفاظت خاک و آبخیزداری- سازمان تحقیقات، آموزش و ترویج کشاورزی، تهران

² استاد پژوهشکده حفاظت خاک و آبخیزداری- سازمان تحقیقات، آموزش و ترویج کشاورزی، تهران

10.22092/wmej.2019.126446.1222

چکیده

آب عنصر اصلی آمایش سرزمین و توسعه‌ی پایدار است، و شناخت و تحلیل ظرفیت‌های منابع آب، پیش‌نیاز برنامه‌ریزی آمایش سرزمین است. در این تحقیق، با بررسی دادههای آب‌دهی روزانه‌ی ایستگاههای آبسنجی استان کرمان، 43 ایستگاه با دوره‌ی مشترک داده‌برداری سالهای 1355-1390 انتخاب شد. مهمترین مولفههای منابع آب سطحی شامل اندازه و پراکندگی فراوانی آب پایه، شاخصهای تداوم جریان، آب‌دهیهای سیلابی، آستانه‌ی شروع روان‌آب، شدت سیلخیزی، ارتفاع توان خط برف و مولفههای بارش محاسبه و تحلیل شد. میانگین شاخص جریان پایه در حوزههای استان 0/61 است و شاخص جریان پایه در حدود 78% از حوزهها بیش از۵۰/۰ است. میانگین ضریب تغییر شاخصهای تداوم جریان 0/11 است. روند تغییر توان خط برف در همه‌ی حوزههای منطقه یکی است. دامنه‌ی آستانه‌ی شروع روان‌آب از 0 تا 25 میلیمتر است که بیشترین فراوانی طبقه‌ی صفر تا پنج با 44/9% پوشش سطحی است. بیش از 50% از زمین‌های استان در طبقه‌ی شدت سیلخیزی کم است. تعداد روزهای بارانی در حدود 50% از حوزه‌های این منطقه بیش از 50 است، و بارش متوسط سالانه‌ی 45% از حوزهها در بازه‌ی 200-300 میلیمتر است. نتیجه‌ی شاخص‌های دست‌رسی به آب پایدار از جمله جریان پایه، ضریب تغییر تداوم جریان و توان خط برف توانایی مناسب حوزههای استان کرمان را برای بهینهسازی طرحهای مرتبط با آب و مهارکردن فشار بر منابع آبهای زیرزمینی در مناطق خشک نشان داد.

کلیدواژه‌ها

عنوان مقاله [English]

Recognition and Analysis of Surface Water Resources Capacity, Prerequisite of Land Use Planning in the Province of Kerman

نویسندگان [English]

Rahim Kazemi ¹
Jahangir Porhemmat ²
Foroud Sharifi ²

¹ Assistant Prof., Soil Conservation and Watershed Management Research Institute, Agricultural Research, Education and Extension Organization, Tehran, Iran

² - Full Prof., Soil Conservation and Watershed Management Research Institute, Agricultural Research, Education and Extension Organization, Tehran, Iran

چکیده [English]

Water is a key element of land use planning and sustainable development, and recognizing and analyzing of water resources capacity is a prerequisite for land use planning. By analyzing the daily stream flow data collected at the hydrometric stations, 43 stations with the common period between 1976 and 2011 in the Province of Kerman were selected. The most important components of the surface water resources including base flow, flow duration curve (FDC) indices, flood discharges, runoff threshold, flood intensity, potential snowfall elevation, and the rainfall components were analysed. The average base flow index in the catchments of the province was 0.61. About 78% of the catchments had a base flow index of more than 0.50. The mean coefficient of variation of the FDC indices was 0.11. Changes in the snow line potential in every catchment of the region followed the same trend. The runoff threshold range was 0 to 25 millimeters and a class of 0 to 5 with 44.9% of the surface coverage was the most frequent, covering the north and northeast of the province. More than 50% of the province land is in the low flood intensity. About 50% of the catchments had more than 50 rainy days and 45% of the catchments were in the range of 200-300 millimetres of average annual precipitation. Results of the sustainable water access indices including base flow index, coefficient of variation of FDC indices and snow line potential showed proper capability of watersheds of the Province of Kerman to optimize the water-related projects and control the overexploitation of the groundwater resources in the arid regions.

کلیدواژه‌ها [English]

Base flow index
catchment
flood frequency
flow duration curve
runoff threshold
water resources planning

مراجع

Abdolahnezhad K. 2015. Forecasting of monthly sum-raining by stochastic models in time series. Geographical Planning of Space Quarterly Journal. 5(17):15–25. (In Persian).

Adeli M. 2012. Evaluation of ground water quality in Gorgan town ship using GIS and geostatistics. Geographical Planning of Space Quarterly Journal. 2(5):57–74. (In Persian).

Ahearn DS, Sheibley RW, Dahlgren RA, Anderson M, Jonson J, Kenneth W.T. 2005. Land use and land cover influence on water quality in the last free-flowing river draining the western Sierra Nevada, California. Journal of Hydrology. 313 :(3-4) 234–247.

Ahmadi A, Karamouz M, Moridi A, Han D. 2012. Integrated planning of land use and water allocation on a watershed scale considering social and water quality issues. Journal of Water Resources Planning and Management. 138 (6): 671–681. (In Persian).

Alipour A, Rahimi J, Azarnivand A. 2017. Groundwater quality analysis for drinking and agricultural purposes-a prerequisite for land use planning in the arid and semi-arid regions of Iran. Journal of Range and Watershed Management. 70(2): 423–434. (In Persian).

Amini A, Haydari R, Hosseini M, Jalali N. 2016. The role of water resources in the land use planning in the Talvar ‎Watershed, Kurdistan, Iran. Watershed Engineering and Management. 8(3):322–331. (In Persian).

Arvin A, Mofidi Kh, Mazini F. 2012. Determination of spatio-temporal pattern of precipitation in Golestan province using cluster analysis. Geographical Planning of Space Quarterly Journal. 5(17):15–25. (In Persian).

Bozorgzadeh A, Mosavi S. J. 2017. Management and development of planning of water resources. Journal of Water and Sustainable Development. 4 (2):179–180. (In Persian).

Christophe B, Tina R. 2015. Integrating water resource management and land-use planning at the rural–urban interface: Insights from a political economy approach. Water Resources and Economics. 1(9): 45–59.

Davies EG, Simonovic SP. 2011. Global water resources modeling with an integrated model of the social– economic–environmental system. Advances in Water Resource. 34(6): 684–700.

FAO. 1993. Guidelines for land use planning. Development Series 1, FAO code: 59 AGRIS: E11, No. ISBN 92(5):103282–103283.

Gyawali S. 2019. Integrating Land use planning and surface water quality management for sustainable development of river basin, a case study of U-tapao river basin, Ph.D. Dissertation, Prince of Songkla University, Thailand. 208 p.

Hedayati-Aghmashhadi A, Jafari H, Mehrdadi N, Fahmi H, Farshchi P, Zahedi S. 2015. Land use planning and water resources management; resource planning instead of activities planning (Case study: Caspian Basin). Journal of Environmental Science and Technology. 17(3):66–86. (In Persian).

Kazemi R, Ghermez-Cheshmeh B. 2016. Investigation of different base flow separation methods using flow duration indices (Case study: Khazar region). Water and Soil Conservation. 23(2): 131–146. (In Persian).

Kazemi R, Sharifi F. 2017. Regional investigation and estimation of base flow index in ‎homogeneous basins of Kerman Providence. Watershed Engineering and Management. 9(1): 97–107. (In Persian).

Khedmati H, manshori M, Heydarizadeh M, Sedghi H. 2010. Zonation and estimation of flood discharge in unguaged sites located in south-east basins of Iran using a combination of flood index and multivariable regression methods (Sistan and Baluchistan, Kerman, Yazd and Hormozgan Provinces), Journal of Water and Soil. 24(3):593–609. (In Persian).

Langat PK, Kumar L, Koech R. 2019. Understanding water and land use within tana and Athi river basins in kenya: opportunities for improvement. Sustainable Water Resources Management. 5(3):977– 987.

Lerner AM, Eakin HC, Tellman E, Bausch JC, Aguilar BH. 2018. Governing the gaps in water governance and land-use planning in a megacity: The example of hydrological risk in Mexico City. Cities Journal. 83(2): 61–70.

Letcher RA, Croke BFW, Jakeman A J, Merritt W S. 2006. An integrated modeling toolbox for water resources assessment and management in highland catchments: model description. Agricultural Systems. 89(1): 106–131.

Ludwig F, Van Slobbe E, Cofino W. 2014. Climate change adaptation and integrated water resource management in the water sector. Journal of Hydrology. 518(2): 235–242.

Lyne V, Hollick M. 1979. Stochastic time variable rainfall runoff modelling. Hydrology and Water Resources Symposium Berth, National Committee on Hydrology and Water Resources of the Institution of Engineers. Australia, 79(10):89–93.

Meire P, Coenen M, Lombardo C, Robba M, Sacile R. 2008. Towards integrated water management. In:Meire P, Coenen, M, Lombardo C, Robba M, Sacile R. (Eds.), Integrated water management, (N.A.T.O, Science Series. IV. Earth and Environmental Sciences, Vol. 80. Springer, Netherlands). ISBN: 978-1-4020-6552-1.

Molinos-Senante M, Herndez- Sancho F, Mochol-Arce M, Sala- Garrido R. 2014. A management and optimization model for water supply planning in water deficit areas. Journal of Hydrology. 515(2): 139–146.

Monshi Zade R, Salehian S. 2015. The Role of water resources in regional sustainable development (case study: Badrood, Isfahan). Geographical Planning of Space Quarterly Journal. 5(17):55–66. (In Persian).

Nouri SH, Seidaiy SE, Kiani S, Soltani Z, Nooruzi-Avargani A. 2010. Assessment of ecologic environmental sources for determining rich farmland by GIS (central district of Kiar Sub County). Geography and Environmental Space. 21(1):33–46. (In Persian).

Palom AR, Pujol DS, Cantos JO. 2017. Sustainable land use planning in areas exposed to flooding: Some international experiences. In Floods; Vinet, F., Ed.; Volume 2 Risk management; Elsevier Ltd.: Amsterdam, The Netherlands. 103–117.

Porhemmat J. 2016. A model on investigation on flood hazard over watersheds of Iran. Iran-Watershed Management Science & Engineering. 10(34):1–14. (In Persian).

Porhemmat J. 2018. Final report of research project: Development and preparation of atlas and spatiotemporal data of flood in 7^th order watersheds of Iran, Ministry of Jihad-e-Agriculture Agricultural Research, Extension and Education Organization, Soil conservation & Watershed Management Research Institute Press, Tehran.415 p. (In Persian).

Porto M.F. A, Porto R.L.L. 2008. Gestão de bacias higrográficas. Estudos Avançados, 22(63): 43–60.

Rodríguez MI, Grindlay AL, Cuevas MM, Zamorano M. 2015. Integrating land use planning and water resource management: threshold scenarios–a tool to reach sustainability. WIT Transactions on Ecology and the Environment. 192(1): 231–242.

Safavi HR, Golmohammadi MH, Sandoval-Solis S. 2015. Expert knowledge-based modeling for integrated water resources planning and management in the Zayandehrud River Basin. Journal of Hydrology. 528(1): 773–789.

Shoaee Z. 2019. Environmental development using rainwater catchment systems.7th National Conference on Rain Water Catchment System. Tehran, Iran. 1(1):46–60. (In Persian).

Supreme Council of the landuse planning of Iran. 2017. National alignment of landuse planning, Approved on 2-5-2017.

Tong S, Chen W. 2002. Modeling the relationship between land use and surface water quality. Journal of Environmental Management. 66(4): 377–393.

Weng SQ, Huang GH, Li YP. 2010. An integrated scenario-based multi-criteria decision support system for water resources management and planning – a case study in the Haihe River Basin. Expert System with Applications. 37(12): 8242–8254.

Xie M. 2006. Integrated water resources management (IWRM) – introduction to principles and practices. In Africa Regional Workshop on I.W.R.M, Nairobi.