SALTMED Model and Its Application on Field Crops, Different Water and Field Management and Under Current and Future Climate Change

详细信息    查看全文

• 关键词：Agadir ; Agricultural water management ; Climate change impact on yield and crop water requirement ; Modelling ; SALTMED model ; Souss ; Massa basin ; Yield
• 刊名：The Handbook of Environmental Chemistry
• 出版年：2017
• 出版时间：2017
• 年：2017
• 卷：53
• 期：1
• 页码：227-274
• 参考文献：1.Choukr-Allah R (2012) Perspectives of wastewater reuse in the Mediterranean region. In: Choukr-Allah R, Ragab R, Rodriguez-Clemente R (eds) Integrated water resources management in the Mediterranean region. Springer, The Netherlands, pp 125–137. doi:10.​1007/​978-94-007-4756-2_​8
  2.Hamdy A, Ragab R, Scarascia ME (2003) Coping with water scarcity: water saving and increasing water productivity. J Irrig Drain 52:3–20CrossRef
  3.Malash NM, Flowers TJ, Ragab R (2008) Effect of irrigation methods, management and salinity of irrigation water on tomato yield, soil moisture and salinity distribution. Irrig Sci 26:313–323CrossRef
  4.Ragab R (2002) A holistic generic integrated approach for irrigation, crop and field management: the SALTMED model. Environ Model Software 17:345–361CrossRef
  5.Ragab R (1997) Constraints and applicability of irrigation scheduling under limited water resources, variable rainfall and saline conditions. Thematic paper (Theme III), ICID-FAO Workshop, Rome, Sept. 12–13, 1995. In: Smith M, Pereira LS, Berengena J, Itier B, Goussard J, Ragab R, Tollefson L, van Hofwegen P (eds) Irrigation scheduling from theory to practice. FAO-ICID Special Publication. Water Reports No. 8. FAO, Rome, pp 149–165
  6.Ragab R (1998) The use of saline/brackish water for irrigation: possibilities and constraints. In Ragab R, Pearce G (eds) Proceedings of an international workshop on the use of Saline and Brackish water for irrigation- implication for the management of irrigation, drainage and crops, 12–41. Bali, Indonesia, July 23–24, 1998. Part of the 49th Annual ICID Conference
  7.Ragab R (2004) Proceedings of the International workshop on “Management of poor quality water for irrigation: Institutional, health and environmental aspects”, Moscow 9–10, 2004. International Commission on Irrigation and drainage, ICID. 276 pp. Available at http://​www.​ICID.​org and at http://​www.​ceh-wallingford.​ac.​uk/​research/​cairoworkshop
  8.Ragab R (2015) Integrated management tool for water, crop, soil and N‐fertilizers: the SALTMED model. Irrig Drain 64:1–12CrossRef
  9.Ragab R (ed) (2005) Advances in integrated management of fresh and saline water for sustainable crop production: modelling and practical solutions. Int J Agric Water Manage (Special Issue) 78(1–2):1–164. Elsevier, Amsterdam, The Netherlands
  10.Ragab R (2010) SALTMED Model as an integrated management tool for water, crop, soil and fertilizers. In: Gheyi, HR, Dias NS, de Lacerda CF (eds) Manejo da salinidade na agricultura: Estudos básicos e aplicados. Instituto Nacional de Ciência e Tecnologia em Salinidade, Fortaleza, Brazil, pp 320–336
  11.Allen GR, Pereira LS, Raes D, Smith M (1998) Crop evapotranspiration. Irrigation and Drainage Paper No. 56. FAO, Rome, Italy
  12.Monteith JL (1965) Evaporation and the environment. In: XIXth symposia of the society for experimental biology. In the state and movement of water in living organisms. University Press, Swansea, pp 205–234
  13.Cardon EG, Letey J (1992) Plant water uptake terms evaluated for soil water and solute movement models. Soil Sci Soc Am J 56:1876–1880CrossRef
  14.Rhoades JD, Kandiah A, Mashali AM (1992) The use of saline waters for crop production. FAO, Irrigation and Drainage Paper No 48. Rome, Italy
  15.Eckersten H, Jansson P-E (1991) Modelling water flow, nitrogen uptake and production for wheat. Fertil Res 27:313–329CrossRef
  16.Hillel D (1977) In: Hillel D (ed) Computer simulation of soil-water dynamics; a compendium of recent work. IDRC, Ottawa, 214 pp
  17.Bresler E (1975) Two-dimensional transport of solute during non-steady infiltration for a trickle source. Soil Sci Soc Am Proc 39:604–613CrossRef
  18.Fletcher Armstrong C, Wilson TV (1983) Computer model for moisture distribution in stratified soils under tickle source. Trans Am Soc Agric Eng 26:1704–1709CrossRef
  19.Ragab R, Feyen J, Hillel D (1984) Simulating two-dimensional infiltration into sand from a trickle line source using the matric flux potential concept. Soil Sci 137:120–127CrossRef
  20.Van Genuchten MT (1980) A closed-form equation for predicting the hydraulic conductivity of unsaturated soils. Soil Sci Soc Am J 44:892–898CrossRef
  21.Kang S, Kim S, Oh S, Lee D (2000) Predicting spatial and temporal patterns of soil temperature based on topography, surface cover and air temperature. For Ecol Manage 136:173–184CrossRef
  22.Zheng D, Hunt J, Running SW (1993) A daily soil temperature model based on air temperature and precipitation for continental applications. Climate Res 2:183–191CrossRef
  23.Johnsson H, Bergstrom L, Jansson P-E (1987) Simulated nitrogen dynamics and losses in a layered agricultural soil. Agric Ecosyst Environ 18:333–356CrossRef
  24.Hooghoudt SB (1940) General consideration of the problem of field drainage by parallel drains, ditches, watercourses, and channels. Publ. No. 7 in the series Contribution to the knowledge of some physical parameters of the soil (titles translated from Dutch). Bodemkundig Instituut, Groningen, The Netherlands
  25.Wesseling J (1973) Subsurface flow into drains. Drainage Principles and Applications Vol. II: Theories of Field Drainage and Watershed Runoff. 2–56. Publ. 16. ILRI, Wageningen, The Netherlands
  26.Jarvis PG (1976) The iterepretation of the variations in leaf water potential and stomatal conductance found in canopies in the field. Philos Trans R Soc B 273:593–610CrossRef
  27.Körner C (1994) Leaf diffusive conductance in the major vegetative types of the globe. In: Schulze ED, Calwell MM (eds) Ecophysiology of photosynthesis, vol 100, Ecol Stud. Springer, Berlin, pp 463–490
  28.Tardieu F, Zhang J, Gowing DJG (1993) Stomatal control by both [ABA] in the xylem sap and leaf water status: a test of a model for droughted or ABA-fed fieldgrown maize. Plant Cell Environ 16:413–420CrossRef
  29.Loague K, Green RW (1991) Statistical and graphical methods for evaluating solute transport models: overview and application. J Contam Hydrol 7:51–73CrossRef
  
• 作者单位：R. Ragab (8)
  R. Choukr-Allah (9)
  A. Nghira (9)
  A. Hirich (9)
  
  8. Centre for Ecology & Hydrology, CEH, Wallingford, Oxon, OX10 8BB, UK
  9. Agronomic and Veterinary Medicine Hassan II Institute, CHA Agadir, 80150, Ait Melloul, Morocco
  
• 丛书名：The Souss‐Massa River Basin, Morocco
• ISBN：978-3-319-51131-3
• 卷排序：53

文摘

Models can be very useful tools in agriculture water management. They could help in irrigation scheduling and crop water requirement estimation and to predict yields and soil salinization. SALTMED model is a generic model that can be used for a variety of irrigation systems, soil types, crops and trees, water application strategies and different water qualities. The early version was successfully tested against field experimental data. The current version, SALTMED 2015, includes additional sub-models, crop growth according to heat units/degree days, crop rotations, nitrogen dynamics, soil temperature, dry matter and yield, subsurface irrigation, deficit irrigation including the Partial Root Drying, PRD, drainage flow to tile or open drains systems, presence of shallow groundwater, evapotranspiration (ET) using Penman–Monteith equation, with different options to obtain the canopy conductance. The current version allows up to 20 fields or treatments to run simultaneously.