Agricultural Engineering

Current Issue

By Issue

By Author

By Subject

Author Index

Keyword Index

About Journal

Aims and Scope

Indexing and Abstracting

Related Links

FAQ

Peer Review Process

The study of sodic soils properties and related formation factors in Abyek plain

Document Type : Research Paper

Authors

Abstract

Introduction Generally, formation and development of sodic soils often appear as almost large in flat plains capable of cultivation, especially in arid and semi-arid regions. Due to their unsuitable characteristics, Slickspots leave bad effects on plants growth and finally on human health. High levels of soluble and exchangeable sodium ions and colloidal material are the main marks of sodic soils. Different surface areas of Slickspot are spread over the flat and arable plains in Iran. The aim of this study was to evaluate the different properties of sodic soils and related soil formation factors in the semi-arid soils of Abyek plain.
Materials and Methods The study area, with the coordinates 35° 47′ - 35° 53′ N and 50° 31′ - 50° 33′ E, was located in the southeastern of Abyek city, Ghazvin providence. Piedmont plain was the main physiography of the area and altitudes were divided in three topographic zones: 1190-1180, 1170-1160, 1150-1140 meters above sea level that the zones were classified into upper, middle and flat parts, respectively. Based on topography and site properties, 13 soil profiles were excavated in the topographic zones and all profiles were described based on USDA Standard Soil Description Manual
Results and Discussion The results showed that soil acidity measured in saturated extraction ranged from 8.6 to 9.1, 9.8 to 9.7 and 9.1 to 10.1 for upper, middle and flat areas, respectively. Field observation studies of upper parts revealed that gravelly and subangular blocky soil structures were found in surface and subsurface horizons, respectively, while the subangular blocky and massive structures were found in subsurface horizons of middle parts profiles. The subangular blocky and columnar structures were demonstrated structures in profiles of the flat areas. Despite the low topography difference, 5 to 10 m in upper lands, exchangeable sodium content and electrical conductivity were low, and saline or sodic soils were not observed. These soils were classified as Xeric Haplocambids. In the middle part with 2 to 5 m difference in elevation, soils were classified as Sodic Xeric Haplocambids and Sodic Xeric Haplocalcids. The white spots observed in the sodic soils were classified as Xeric and Vertic Natrargids. Compare with the adjacent areas, the concentration of carbonate and bicarbonate anions were relatively high in soils of the flat areas that led to considerable increase in soil acidity. This can shows the accumulation of sodium carbonate salts in the soils. The presence of carbonate and bicarbonate anions in middle areas, probably was due to the development of Sodicization in the soils. The XRD diffractometers showed illite, montmorilonite, chlorite and palygorskite as the clay minerals in soil heorizons. Illite was found in all soil horizons of flat areas with deep decline. This decline was along with increasing of smectite clay minerals in Natric horizons that had poor drainage conditions. The clay coatings in the natric horizons were confirmed by micromorphology and scanning electron microscopy techniques. The cumulative clays on external surfaces of soil aggregates and wall pores, in flat areas, revealed the clay eluviation process. Because of the high soluble and exchangeable sodium cations, the conditions were favorable for transfer of clay in the soils, even in the presence of lime.
Conclusion Consequently, the main soil formation factors in sodic soils can be presented as different in soil positions on piedmont physiography, the local relief, lateral and vertical movement of water and soluble salts from neighboring areas into the downstream lands and also salt and sodium containing minerals deposited by wind. The Slickspots and related soils were one of the major terrestrial phenomena in the plain Abyek. The Sodic soils in the plain were formed in the absence of high ground water table. Other environmental factors such as micro reliefs, position on the Landform, lateral movement of water and soluble salts and windborne sediments, played and essential role in the formation of sodic soils. The results of the experiments indicated that Sodicization process is developing towards the adjacent land and the absence of gypsum accelerated this development in these areas. Also, mineralogical studies indicate the presence of smectite mineral clay in Natric horizon where the drainage condition was poor and gave the possibility of neoformation of smectite, and that clay movement evidence from upper parts of profile was confirmed by micromorphological studies.

Keywords

References
  1. Abtahi, A. 1977. Effect of a saline and alkaline ground water on soil genesis in semiarid southern Iran. Soil Science Society of America Journal, 41: 583-588.
  2. Azizi, P., Mahmoodi, S., Torabi, H., Masihabadi, M.H., and Homaee, M. 2011. Morphological, physicochemical and clay mineralogy investigation on gypsiferous soils in Southern of Tehran, Iran. Middle East Journasl, 7: 153-161.
  3. Banaei, M.H. 1998. Soil moisture and temperature regime map of Iran. Soil and Water research institute. Ministry of agriculture, Tehran, Iran.
  4. Barnhisel R.I., and Bertsch P.M. 1989. Chlorites and hydroxy-in-terlayered vermiculite and smectite. In Dixon, J.B., and Weed, S.B (eds.), Minerals in Soil Environments: 2nd ed. Soil Science Society of America Book Series, Vol.1, Madison, Wisconsin, USA. pp: 729-788.
  5. Bhargava, G.P., Pal, D.K., Kapoor, B.S., and Goswami, S.C. 1981. Characteristics and genesis of some sodic soils in the Indo-Gangetic alluvial plains of Haryana and Uttar Pradesh. Journal of the Indian Society of Soil Science, 29(1): 61-70
  6. Borchardt, G. 1989. Smectites. In Dixon, J.B., and Weed, S.B (eds.), Minerals in Soil Environments: 2nd ed. Soil Science Society of America Book Series, Vol.1, Madison, Wisconsin, USA. pp: 675-727
  7. Bower, C.A., and Hatchea, J.T. 1966. Simultaneous determination of surface area and cation exchange capacity. Soil Science Society of America Journal, 30:525-527.
  8. Bristow, T.F., and Milliken, R.E. 2011. A terrestrial perspective on authigenic clay mineral production in ancient Martian lakes. Clay and Clay Mineral, 59: 339-358.
  9. Chorom, M., Baghernejad, M., and Jafari, S. 2009. Influence of rotation cropping and sugarcane production on the clay mineral assemblage. Appleid Clay Science, 46: 385-395.
  10. Deocampo, D.M. 2010. Geochemistry of continental carbonates. In Alonso-Zarza, A.M., and Tanner, L.H. (eds), Carbonates in continentals Settings: Geochemistry, Diagenesis, and Applications: Developments in Sedimentology, vol. 62, Elsevier, Amsterdam. pp: 1-59
  11. Fanning, D.S., and Fanning, M.C.B. 1989. Soil: Morphology, genesis, and classification. John. Wiley and Sons, New York. pp: 395.
  12. Fullerton, S., and Pawluk, S. 1987. The role of seasonal salt and water fluxes in the genesis of. Solonetzic B horizons. Canadian Journal of Soil Science, 67: 719-730.
  13. Gee, G.W., and Bauder, J.W.1986. Particle-size analysis. In Klute, A. (ed), Methods of Soil Analysis, Part.I, Physical and mineralogical methods, 2nd ed., Agronomy Monograph, No: 9. ASA and SSSA, Madison, Wisconsin, USA. pp: 383-411.
  14. Geological map of Eshtehard, Scale 1:100000, Geological Survey and Mineral Exploration of Iran.
  15. Heck, R.J., and Mermut, A.R. 1992. Genesis of Natriborolls. (Solonetzic) in a closed lake basin in Saskatchewan, Canada. Soil Science Society of America Journal, 56:842-848.
  16. Hopkins, D.G., Sweeney, M.D., and Richardson, J.L. 1991. Dispersive erosion and Entisol-panspot genesis in sodium-affected landscapes. Soil Science Society of America Journal, 55(1): 171-177.
  17. Joeckel, R.M., and Ang Clement, B.J. 2005. Soils, surficial geology, and geomicrobiology of saline-sodic wetlands, North Platte River Valley, Nebraska, USA. Catena, 61(1): 63-101.
  18. Johnson, W.F., Mausbach, M.J., Gamble, E.E., and Nelson, R.E. 1985. Natric horizons on some erosional landscapes in Northwestern South Dakota. Soil Science Society of America Journal, 49:947-952.
  19. Khormali, F., and Abtahi, A. 2003. Origin and distribution of clay minerals in calcareous arid and semiarid soils of Fars province, southern Iran. Clay Mineral, 38: 511-527.
  20. Khresat, S.A., and Qudah, E.A. 2006. Formation and properties of aridic soils of Azraq Basin in Northeastern Jordan. Jornal of Arid Environment, 64: 116-136.
  21. Khresat, S.A., Rawajfih, Z., Buck, B., and Monger, H.C. 2004. Geomorphic features and soil formation of arid lands in Northeast Jordan. Archieve of Agronomy and Soil Science, 50:607-615.
  22. Kittrick, J.A. and Hope, E.W. 1963. A procedure for particle size separation of soils for X-ray diffraction analysis. Soil Science, 96: 312-325.
  23. Lanyon, L.E., and Heald, W.R. 1982. Magnesium, Calcium, Strontium and Barium. In Page, A.L et al. (eds), Methods of Soil Analysis, Part II, Chemical and microbiological properties, 2nd ed, Agronomy Monograph. No: 9. ASA and SSSA, Madison, Wisconsin, USA. pp: 247-260
  24. McKeague, J.A., Wang, C., Ross, G.J., Acton, C.J., Smith, R.E., Anderson, D.W., Pettapiece, W.W., and Lord, T.M. 1981. Evaluation of criteria for argillic horizons (Bt) of soils in Canada. Geoderma, 25:63-74.
  25. Munn, L.C., and Boehm, M.M. 1983. Soil genesis in a Natrargid-Haplargid complex in northem Montana. Soil Science Society of America Journal, 47: 1186-1192.
  26. Nabiollahy, K., Khormali, F., Bazargan, K., and Ayoubi, SH. 2006. Forms of potassium as a function of clay mineralogy and soil development. Clay Minerals, 41: 739-749.
  27. Nelson, D.W., and Sommers, L.E. 1982. Total Carbon, Organic Carbon and Organic Matter. In Page, A.L, et al (eds), Methods of Soil Analysis. Part II, Chemical and microbiological properties, 2nd ed., Agronomy Monograph, No: 9. ASA and SSSA. Madison, Wisconsin, USA. pp: 539-577
  28. Nelson, R.E. 1982. Carbonate and Gypsum. P: 181-196. In: Page, A.L, et al. (Eds), Methods of Soil Analysis. Part II. Chemical and microbiological properties, 2nd ed., Agronomy Monograph. No: 9. ASA and SSSA. Madison, Wisconsin, USA.
  29. Owliaie, H.R., Abtahi, A., and Heck, R.J. 2006. Pedogenesis and clay mineralogical investigation of soils formed on gypsiferous and calcareous materials, on a transect, Southwestern Iran. Geoderma, 134: 62- 81.
  30. Pal, D.K., Srivastava, P., and Bhattacharyya, T. 2003. Clay illuviation in calcareous soils of the semiarid part of the Indo-Gangetic Plains, India. Geoderma, 115(3): 177-192
  31. Pal, D.K., Srivastava, P., Durge, S.L., and Bhattacharyya, T. 2003. Role of microtopography in the formation of sodic soils in the semi-arid part of the Indo-Gangetic Plains, India. Catena, 51(1): 3-31.
  32. Pal, D.K., Kalbande, A.K., Deshpande, S.B., and Sehgal, J.L. 1994. Evidence of clay illuviation in sodic soils of the Indo-Gangetic plain since the Holocene. Soil. Science, 158: 465-473.
  33. Pal, D.K., Srivastava, P., Durge, S.L., and Bhattacharyya, T. 2003. Role of microtopography in the formation of sodic soils in the semi-arid part of the Indo-Gangetic Plains, India. Catena, 51: 3-31.
  34. Pawluk, S. 1982. Salinization and Solonetz formation. In Proc. 19th Alberta Soil Science. Workshop. Edmonton, Alberta. pp: 1–23
  35. Qadir, M., and Oster, J.D. 2004. Crop and irrigation management strategies for saline sodic soils and waters aimed at environmentally sustainable agriculture. Science of the Total Environment, 323: 1–19.
  36. Reid, D.A., Graham, R.C., Amrhein, C., and Southard, R.J. 1993. Slickspot soil genesis in the Carrizo Plain, California. Soil Science Society of America Journal, 57(1): 162-168.
  37. Richards, L.A. 1954. Diagnosis and Improvement of Saline and Alkaline Soils. United States Salinity. Laboratory Staff. Agricultural Handbook, No 60.
  38. Schoeneberger, P.J., Wysocki, D.A., Benham, E.C., and Broderson, W.D. 2012. Fieldbook for. Describing and Sampling Soils. Natural Resources Conservation Service, National Soil Survey Center, Lincoln, NE.
  39. Seelig, B.D., and Richardson, J.L. 1994. Sodic soil toposequence related to focused water flow. Soil Science Society of America Journal, 58(1): 156-163.
  40. Singer, A., and Norrish, K. 1974. Pedogenic palygorskite occurrences in Australia. American Mineralogist, 59:508-517.
  41. Soil Survey Staff. 2014. Keys to Soil Taxonomy, 12th ed. USDA-Natural Resources Conservation Service, Washington, DC.
  42. Stoops, G. 2003. Guidelines for the analysis and description of soil and regolith. Thin Sections. SSSA. Inc. Madison, Wisconsin.
Agricultural Engineering
Volume 39, Issue 1
August 2016
Pages 145-160
Files
Share
How to cite
Statistics