Enhancing the Productivity of High-Magnesium Soil and Water Resources in Central Asia

  • Manzoor Qadir
  • Frants Vyshpolsky
  • Khamit Mukhamedjanov
  • Ussen Bekbaev
  • Saghit Ibatullin
  • Tulkun Yuldashev
  • Andrew D. Noble
  • Akmal Karimov
  • Alisher Mirzabaev
  • Aden Aw-Hassan
Chapter
First Online:
Part of the Environmental Science and Engineering book series (ESE)

Abstract

High-magnesium soils and waters are emerging environmental and agricultural productivity constraints. Excess levels of magnesium (Mg2+) in irrigation waters and/or in soils negatively affect soil infiltration rate and hydraulic conductivity and ultimately crop growth and yield. Although the levels of Mg2+ in irrigation waters and soils are increasing in several irrigation schemes globally, southern Kazakhstan has become a hotspot of such natural resource degradation. The productivity of magnesium-affected soils can be enhanced by increasing the levels of calcium (Ca2+) in the soil to counteract the negative impacts of Mg2+. Studies undertaken on the soil application of phosphogypsum, a major waste product of phosphoric acid factories and a source of Ca2+, have demonstrated beneficial effects of this soil amendment in terms of (1) improved soil quality through a reduction in exchangeable magnesium percentage (EMP) levels; (2) enhanced water movement into and through the soil vis-à-vis increased moisture storage in the soil for use by the plant roots; (3) increased cotton yield and water productivity; and (4) greater financial benefits. In addition to improving crop productivity, these studies demonstrated the beneficial use of an industrial waste material in agriculture. With the aim of addressing the challenge of achieving sustainable agriculture production from magnesium-affected environments, there would be a need for appropriate supportive policies and functional institutions along with capacity building of farmers, researchers, and agricultural extension workers.

Keywords

Magnesium to calcium ratio Exchangeable magnesium percentage Salt-affected soils Phosphogypsum Water quality Central Asia Kazakhstan Cotton 
This is a preview of subscription content, log in to check access.

References

  1. Alcordo IS, Rechcigl JE (1993) Phosphogypsum in agriculture: a review. Adv Agron 49:55–118CrossRefGoogle Scholar
  2. Al-Oudat M, Arslan A, Kanakri S (1998) Physical and chemical properties, plant growth, and radionuclide accumulation effects from mixing phosphogypsum with some soils. Comm Soil Sci Plant Anal 29:2515–2528CrossRefGoogle Scholar
  3. Bekbaev R, Vyshpolsky F, Ibatullin S, Mukhamedjanov Kh, Bekbaev U (2005) Influence of application of phosphogypsum on infiltration rate of solonetzic soil. Bull Agric Sci Kazakhstan 7:18–20 (in Russian)Google Scholar
  4. Bohn HL, McNeal BL, O’Connor GA (1985) Soil chemistry. Wiley, New YorkGoogle Scholar
  5. Dontsova KM, Norton LD (2002) Clay dispersion, infiltration and erosion as influenced by exchangeable Ca and Mg. Soil Sci 167:184–193CrossRefGoogle Scholar
  6. El-Mrabet R, Abril JM, Perianez R, Manjon G, Garcia-Tenorio R, Delgado A, Andreu L (2003) Phosphogypsum amendment effect on radionuclide content in drainage water and marsh soils from southwest Spain. J Environ Qual 32:1262–1268CrossRefGoogle Scholar
  7. Garcia-Ocampo A (2003) Physical properties of magnesium affected soils in Colombia. Lecture given at the College on Soil Physics, 3–21 March 2003, TriesteGoogle Scholar
  8. Ghafoor A, Shahid MI, Saghir M, Murtaza G (1992) Use of high-Mg brackish water on phosphogypsum and FYM treated saline-sodic soil. I. Soil improvement. Pak J Agric Sci 29:180–184Google Scholar
  9. Karajeh F, Karimov A, Mukhamedjanov V, Vyshpolsky F, Mukhamedjanov KH, Ikramov R, Palvanov T, Novikova A (2004) Improved on-farm water management strategies in Central Asia. In: Ryan J, Vlek P, Paroda R (eds) Agriculture in Central Asia: research for development. ICARDA, Aleppo, Syria, and Center for Development Research, Bonn, pp 76–89Google Scholar
  10. Karimov A, Qadir M, Noble A, Vyshpolsky F, Anzelm K (2009) The development of magnesium-dominant soils under irrigated agriculture in southern Kazakhstan. Pedosphere 19:331–343CrossRefGoogle Scholar
  11. Keren R (1991) Specific effect of magnesium on soil erosion and water infiltration. Soil Sci Soc Am J 55:783–787CrossRefGoogle Scholar
  12. Levy GJ, van der Watt HVH, du Plessis HM (1988) Effect of Na/Mg and Na/Ca systems on soil hydraulic conductivity and infiltration rate. Soil Sci 146:303–310Google Scholar
  13. McNeal BL, Layfield DA, Norvell WA, Rhoades JD (1968) Factors influencing hydraulic conductivity of soils in the presence of mixed-salt solutions. Soil Sci Soc Am Proc 32:187–190CrossRefGoogle Scholar
  14. Oster JD, Jayawardane NS (1998) Agricultural management of sodic soils. In: Sumner ME, Naidu R (eds) Sodic soil: distribution, management and environmental consequences. Oxford University Press, New York, pp 126–147Google Scholar
  15. Qadir M, De Pauw E (2007) Emerging challenges addressing the characterization and mapping of salt-induced land degradation. Presented at the first expert consultation meeting of the global network on salinization prevention and productive use of salt-affected habitats (SPUSH), 26–29 November 2007, Dubai, United Arab EmiratesGoogle Scholar
  16. Qadir M, Schubert S (2002) Degradation processes and nutrient constraints in sodic soils. Land Degrad Dev 13:275–294CrossRefGoogle Scholar
  17. Qadir M, Noble AD, Chartres C (2013) Adapting to climate change through improved water productivity of soils in dry areas. Land Degrad Dev 24:12–21CrossRefGoogle Scholar
  18. Rengasamy P, Greene RSB, Ford GW (1986) Influence of magnesium on aggregate stability in sodic Red-Brown Earths. Aust J Soil Res 24:229–237CrossRefGoogle Scholar
  19. Vyshpolsky F, Qadir M, Karimov A, Mukhamedjanov K, Bekbaev U, Paroda R, Aw-Hassan A, Karajeh F (2008) Enhancing the productivity of high-magnesium soil and water resources through the application of phosphogypsum in Central Asia. Land Degrad Dev 19:45–56CrossRefGoogle Scholar
  20. Vyshpolsky F, Mukhamedjanov K, Bekbaev U, Ibatullin S, Yuldashev T, Noble AD, Mirzabaev A, Aw-Hassan A, Qadir M (2010) Optimizing the rate and timing of phosphogypsum application to magnesium-affected soil for crop yield and water productivity enhancement. Agric Water Manag 97:1277–1286CrossRefGoogle Scholar

Copyright information

© Springer International Publishing Switzerland 2014

Authors and Affiliations

  • Manzoor Qadir
    • 1
  • Frants Vyshpolsky
    • 2
  • Khamit Mukhamedjanov
    • 2
  • Ussen Bekbaev
    • 2
  • Saghit Ibatullin
    • 3
  • Tulkun Yuldashev
    • 4
  • Andrew D. Noble
    • 5
  • Akmal Karimov
    • 6
  • Alisher Mirzabaev
    • 4
  • Aden Aw-Hassan
    • 7
  1. 1.United Nations University—Institute for WaterEnvironment and Health (UNU-INWEH)HamiltonCanada
  2. 2.Kazakh Scientific Research Institute of Water EconomyWater Quality LaboratoryTarazKazakhstan
  3. 3.Executive Committee of the International Fund for Saving the Aral Sea (EC-IFAS)AlmatyKazakhstan
  4. 4.ICARDACentral Asia and Caucasus Regional OfficeTashkentUzbekistan
  5. 5.International Water Management Institute (IWMI)ColomboSri Lanka
  6. 6.IWMI—Central AsiaC/O PFU-CGIAR-ICARDA-CACTashkentUzbekistan
  7. 7.International Center for Agricultural Research in the Dry Areas (ICARDA)AleppoSyria

Personalised recommendations