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Reclamation of Saline and Sodic Soil Through Phytoremediation

  • Neerja Srivastava
Chapter

Abstract

Agricultural productivity is threatened worldwide because of salt-affected soils. Various remediation techniques have been successfully developed and are being utilized, but still there is no proper technical method under different conditions. In different situations, phytoremediation technically as well as economically is the best available option. More focussed efforts are required to measure the contribution of phytoextraction to the remedial procedure because the main mechanism behind salt phytoremediation is still not known. To improve the effectiveness and quality of the treatment of salt-affected soils, many new methods are used like mixing of treatment types, mixed plant cultures, biostimulation, etc. which can be extended to new methods like co-treatment and salt flow control measures. The new methods are in preliminary stages that require further research.

Keywords

Phytoremediation Saline soil Sodic soil Saline-sodic soil 

References

  1. Abideen Z, Ansari R, Khan MA (2011) Halophytes: potential source of ligno-cellulosic biomass for ethanol production. Biomass Bioenergy 35:1818–1822.  https://doi.org/10.1016/j.biombioe.2011.01.023CrossRefGoogle Scholar
  2. Adams AA, Raman A, Hodgkins D (2013a) How do the plants used in phytoremediation in constructed wetlands, a sustainable remediation strategy, perform in heavy-metal-contaminated mine sites? Water Environ J27:373–386Google Scholar
  3. Adams AA, Raman A, Hodgkins D, Nicol HI (2013b) Accumulation of heavy metals by naturally colonizing Typha domingensis (Poales: Typhaceae) in waste-rock dump leachate storage ponds in a gold–copper mine in the central tablelands of New South Wales, Australia. Int J Min Reclam Environ 27:294–307CrossRefGoogle Scholar
  4. Ahmad N, Qureshi RH, Qadir M (1990) Amelioration of a calcareous saline-sodic soil by gypsum and forage plants. Land Degrad Rehabil 2(4):277–284CrossRefGoogle Scholar
  5. Allen RB, McIntosh PD, Wilson JB (1997) The distribution of plants in relation to pH and salinity on inland saline/alkaline soils in Central Otago, New Zealand. N Z J Bot 35:517–523CrossRefGoogle Scholar
  6. Ammari T, Tahboub AB, Saoub HM, Hattar BI, Al-Zubi YA (2008) Salt removal efficiency as influenced by phyto-amelioration of salt-affected soils. J Food Agric Environ 6:456–460Google Scholar
  7. Amer N, Chami ZA, Bitar LA, Mondelli D, Dumontet S (2013) Evaluation of Atriplex halimus, Medicago lupulina and Portulaca oleracea for phytoremediation of Ni, Pb, and Zn. Int J Phytorem 15:498–512CrossRefGoogle Scholar
  8. Ammari TG, Al-Hiary S, Al-Dabbas M (2011) Reclamation of saline calcareous soils using vegetative bioremediation as a potential approach. Arch Agron Soil Sci 59:1–9.  https://doi.org/10.1080/03650340.2011.629813CrossRefGoogle Scholar
  9. Aprill W, Sims RC (1990) Evaluation of the use of prairie grasses for stimulating polycyclic aromatic hydrocarbon treatment in soil. Chemosphere 20:253–265CrossRefGoogle Scholar
  10. Arienzo M, Adamo P, Cozzolino V (2004) The potential of Lolium perenne for revegetation of contaminated soil from a metallurgical site. Sci Total Environ 319:13–25CrossRefGoogle Scholar
  11. Aslam M, Prathapar SA (2006) Strategies to mitigate secondary salinization in the Indus Basin of Pakistan: a selective review. Research Report 97. International Water Management Institute (IWMI), Colombo, Sri LankaGoogle Scholar
  12. Aydemir S, Akıl HS (2012) Growth response and ameliorative effect of a forage plant (Festuca arundinacea) in calcareous saline-sodic soils. Afr J Agric Res 7(5):802–809Google Scholar
  13. Baker AJM, McGrath SP, Sidoli CMD, Reeves RD (1994) The possibility of in situ metal decontamination of polluted soils using crops of metal-accumulating plants – a feasibility study. Resour Conserv Recycl 11:41–49CrossRefGoogle Scholar
  14. Barbour MG, Burk JH, Pitts WD (1987) Terrestrial plant ecology, 2nd edn. Benjamin Cummings Publishing, Menlo ParkGoogle Scholar
  15. Barrett-Lennard EG (1986) Effects of water logging on the growth and NaCl uptake by vascular plants under saline conditions. Reclam Reveg Res 5:245–261Google Scholar
  16. Barrett-Lennard EG (2002) Restoration of saline land through revegetation. Agric Water Manag 53:213–226CrossRefGoogle Scholar
  17. Batra L, Kumar A, Manna MC, Chhabra R (1997) Microbiological and chemical amelioration of alkaline soil by growing Karnal grass and gypsum application. Exp Agric 33:389–397CrossRefGoogle Scholar
  18. Bhuiyan MSI, Raman A, Hodgkins DS (2017) Plants in remediating salinity-affected agricultural landscapes. Proc Indian Natl Sci Acad 83(1):51–66Google Scholar
  19. Bleby TM, Aucote M, Kennett-Smith AK, Walker GR, Schachtman DP (1997) Seasonal water use characteristics of tall wheatgrass [Agropyron elongatum (Host) Beauv.] in a saline environment. Plant Cell Environ 20:1361–1371CrossRefGoogle Scholar
  20. Brady NC, Weil RR (1996) The nature and properties of soils. Prentice Hall, Upper Saddle RiverGoogle Scholar
  21. Cai X, McKinney DC, Rosegrant MW (2003) Sustainability analysis for irrigation water management in the Aral Sea region. Agric Syst 76:1043–1066CrossRefGoogle Scholar
  22. Chengrui M, Dregne HE (2001) Silt and the future development of China’s Yellow River. Geogr J 167:7–22CrossRefGoogle Scholar
  23. Cheraghi SAM (2001) Institutional and scientific profiles of organizations working on saline agriculture in Iran. In: Taha FK, Ismail S, Jaradat A (eds) Prospects of saline agriculture in the Arabian Peninsula. Proceedings of the International seminar on prospects of saline agriculture in the GCC countries 18. Dubai, United Arab Emirates, pp 399–412Google Scholar
  24. Chhabra R, Abrol IP (1977) Reclaiming effect of rice grown in sodic soils. Soil Sci 124:49–55CrossRefGoogle Scholar
  25. Dagar JC, Tomar OS, Kumar Y, Yadav RK (2004) Growing three aromatic grasses in different alkali soils in semi-arid regions of northern India. Land Degrad Dev 15:143–151CrossRefGoogle Scholar
  26. De Villiers AJ, Van Rooyen MW, Theron GK, Claassens AS (1995) Removal of sodium and chloride from a saline soil by Mesembryanthemum barklyi. J Arid Environ 29(3):325–330CrossRefGoogle Scholar
  27. deSigmond AAJ (1924) The alkali soils in Hungary and their reclamation. Soil Sci 18:379–381CrossRefGoogle Scholar
  28. Diaz DR, Presley D (2017) Management of saline and sodic soils. Kansas State University, ManhattanGoogle Scholar
  29. El-Shakweer MHA, El-Sayad EA, Ejes MSA (1998) Soil and plant analysis as a guide for interpretation of the improvement efficiency of organic conditioners added to different soils in Egypt. Commun Soil Sci Plant Anal 29:2067–2088CrossRefGoogle Scholar
  30. Fageria NK, Gheyi HR, Moreira A (2011) Nutrient bioavailability in salt affected soils. J Plant Nutr 34(7):945–962.  https://doi.org/10.1080/01904167.2011.555578CrossRefGoogle Scholar
  31. Fitter AH, Nichols R, Harvey ML (1988) Root system architecture in relation to life history and nutrient supply. Funct Ecol 2:345–351CrossRefGoogle Scholar
  32. Flowers TJ, Colmer TD (2008) Salinity tolerance in halophytes. New Phytol 179:945–963CrossRefGoogle Scholar
  33. Frick CM, Germida JJ, Farrell RE (1999) Assessment of phytoremediation as an in-situ technique for cleaning oil-contaminated sites. Petroleum Technology Alliance of Canada Calgary CanadaGoogle Scholar
  34. Gamalero E, Lingua G, Berta G, Glick BR (2009) Beneficial role of plant growth promoting bacteria and arbuscular mycorrhizal fungi on plant responses to heavy metal stress. Can J Microbiol 55(5):501–514.  https://doi.org/10.1139/w09-010CrossRefGoogle Scholar
  35. Garbisu C, Alkorta I (2001) Phytoextraction: a cost-effective plant-based technology for the removal of metals from the environment. Bioresour Technol 77:229–236CrossRefGoogle Scholar
  36. Gaskin SE (2008) Rhizoremediation of hydrocarbon contaminated soil using Australian native grasses. PhD thesis, Flinders University of South Australia, Australia. http://flex.flinders.edu.au/file/6bbe0809-457c-4c15-8caf-ea59d4fea600/1/Thesis-Gaskin-2009-Abstract.pdf
  37. Gatliff EG (1994) Vegetative remediation process offers advantages over traditional pump-and-treat technologies. Remediat J 4:343–352CrossRefGoogle Scholar
  38. Ghaly FM (2002) Role of natural vegetation in improving salt affected soil in northern Egypt. Soil Tillage Res 64:173–178CrossRefGoogle Scholar
  39. Gharaibeh MA, Eltaif NI, Shra’ah SH (2010) Reclamation of a calcareous saline-sodic soil using phosphoric acid and by-product gypsum. Soil Use Manag 26(2):141–148CrossRefGoogle Scholar
  40. Gharaibeh MA, Eltaif NI, Albalasmeh AA (2011) Reclamation of highly calcareous saline sodic soil using Atriplex halimus and by-product gypsum. Int J Phytorem 13:873–883CrossRefGoogle Scholar
  41. Ghassemi F, Jakeman AJ, Nix HA (1995) Salinisation of land and water resources: human causes, extent, management and case studies. CABI Publishing, WallingfordGoogle Scholar
  42. Glenn EP, Brown JJ, Blumwald E (1999) Salt tolerance and crop potential of halophytes. Crit Rev Plant Sci 18(2):227–255CrossRefGoogle Scholar
  43. Glenn EP, Anday T, Chaturvedi R, Martinez-Garcia R (2013) Three halophytes for saline-water agriculture: an oilseed, a forage and a grain crop. Environ Exp Bot 92:110–121.  https://doi.org/10.1016/j.envexpbot.2012.05.002CrossRefGoogle Scholar
  44. Graifenberg A, Botrini L, Giustiniani L, Filippi F, Curadi M (2003) Tomato growing in saline conditions with biodesalinating plants: Salsola soda L. and Portulaca oleracea L. Acta Hortic 609:301–305CrossRefGoogle Scholar
  45. Grattan SR, Grieve CM, Poss JA, Robinson PH, Suarez DL, Benes SE (2004) Evaluation of salt-tolerant forages for sequential water reuse systems III Potential implications for ruminant mineral nutrition. Agric Water Manag 70:137–150Google Scholar
  46. Greenwood ME, MacFarlane GR (2006) Effects of salinity and temperature on the germination of Phragmites australis, Juncus kraussii, and Juncus acutus: implications for estuarine restoration initiatives. Wetlands 26:854–861CrossRefGoogle Scholar
  47. Guittonny-Philippe A, Masotti V, Höhener P, Boudenne JL, Viglione J, Laffont-Schwob I (2014) Constructed wetlands to reduce metal pollution from industrial catchments in aquatic Mediterranean ecosystems: a review to overcome obstacles and suggest potential solutions. Environ Int 64:1–16CrossRefGoogle Scholar
  48. Gul B, Weber DJ, Khan MA (2000) Effect of salinity and planting density on physiological responses of Allenrolfea occidentalis. West N Am Nat 60(2):188–197Google Scholar
  49. Gupta RK, Abrol IP (1990) Salt-affected soils: their reclamation and management for crop production. Adv Soil Sci 11:223–288CrossRefGoogle Scholar
  50. Gupta, RK, and Abrol IP. (2000). Salinity build-up and changes in the rice-wheat system of the Indo-Gangetic Plains. Exp. Agric. 36: 273–284.CrossRefGoogle Scholar
  51. Hameed M, Ashraf M (2008) Physiological and biochemical adaptations of Cynodon dactylon (L.) Pers. from the salt range (Pakistan) to salinity stress. Flora 203:683–694CrossRefGoogle Scholar
  52. Hasanuzzaman M, Nahar K, Alam MM, Bhowmik PC, Hossain MA, Rahman MM, Prasad MNV, Ozturk M, Fujita M (2014) Potential use of halophytes to remediate saline soils. Biomed Res Int 2014:58934112.  https://doi.org/10.1155/2014/589341CrossRefGoogle Scholar
  53. Hayley K, Bentley LR, Gharibi M (2009) Time-lapse electrical resistivity monitoring of salt-affected soil and groundwater. Water Resour Res 45.  https://doi.org/10.1029/2008WR007616
  54. Herczeg AL, Dogramaci SS, Leany FWJ (2001) Origin of dissolved salts in a large, semi-arid groundwater system. Murray Basin, Australia. Mar Freshw Res 52:41–52CrossRefGoogle Scholar
  55. Horneck DA. Ellsworth JW, Hopkins BG, Sullivan DM, Stevens RG (2007) Managing salt-affected soils for crop production. PNW 601-E A Pacific Northwest Extension publication Oregon State University • University of Idaho • Washington State UniversityGoogle Scholar
  56. Huang JW, Chen J (2005) Role of pH in phytoremediation of contaminated soils. In: Rengel Z (ed) Handbook of soil acidity. Mercel Dekker, New York, pp 449–472Google Scholar
  57. Hutchinson S, Schwab A, Banks M (2003) Biodegradation of petroleum hydrocarbons in the rhizosphere. In: McCutcheon S, Schnoor J (eds) Phytoremediation: transformation and control of contaminants. Wiley, New York, pp 355–386CrossRefGoogle Scholar
  58. Ilyas M, Miller RW, Qureshi RH (1993) Hydraulic conductivity of saline-sodic soil after gypsum application and cropping. Soil Sci Soc Am J 57:1580–1585CrossRefGoogle Scholar
  59. Ilyas M, Qureshi RH, Qadir M (1997) Chemical changes in a saline-sodic soil after gypsum application and cropping. Soil Technol 10:247–260CrossRefGoogle Scholar
  60. Imada S, Yamanaka N, Tamai S (2009) Effects of salinity on the growth, Na partitioning, and Na dynamics of a salt tolerant tree, Populus alba L. J Arid Environ 73:245–251CrossRefGoogle Scholar
  61. Jesus JM, Danko AS, Fiúza A, Borges M (2015) Phytoremediation of salt-affected soils: a review of processes, applicability, and the impact of climate change. Environ Sci Pollut Res 22(9):6511–6525CrossRefGoogle Scholar
  62. Jithesh MN, Prashanth SR, Sivaprakash KR, Parida AK (2006) Antioxidative response mechanisms in halophytes: their role in stress defence. J Genet 85(3):237–254CrossRefGoogle Scholar
  63. Kelley WP (1937) The reclamation of alkali soils. Calif Agric Exp Stn Bull 617:1–40Google Scholar
  64. Kelley WP (1951) Alkali soils: their formation, properties, and reclamation, vol 72. Reinhold, New York, p 403Google Scholar
  65. Kelley WP, Brown SM (1934) Principles governing the reclamation of alkali soils. Hilgardia 8:149–177CrossRefGoogle Scholar
  66. Khan AL, Hamayun M, Ahmad N, Hussain J, Kang SM, Kim YH, Adnan M, Tang DS, Waqas M, Radhakrishnan R, Hwang YH, Lee IJ (2011) Salinity stress resistance offered by endophytic fungal interaction between Penicillium minioluteum LHL09 and Glycine max L. J Microbiol Biotechnol 21:893–902CrossRefGoogle Scholar
  67. Knight EW (1935) Agricultural investigation on the Newlands (Nev.) reclamation project. USDA Res Tech Bull 464:1–35Google Scholar
  68. Kömives T, Gullner G (2000) Phytoremediation. In: Wilkinson RE (ed) Plant-environment interactions. Marcel Dekker, New York, pp 437–452Google Scholar
  69. Kumar A, Abrol IP (1984) Studies on the reclaiming effect of Karnal grass and para-grass grown in a highly sodic soil. Indian J Agric Sci 54:189–193Google Scholar
  70. Larcher W (1980) Physiological plant ecology, 2nd edn. Springer, New YorkCrossRefGoogle Scholar
  71. Leahy JG, Colwell RR (1990) Microbial degradation of hydrocarbons in the environment. Microbiol Rev 54:305–315Google Scholar
  72. Liu X, Huang W, Niu Z, Mori S, Tadano T (2008) Interactive effect of moisture levels and salinity levels of soil on the growth and ion relations of halophyte. Commun Soil Sci Plant Anal 39:741–752CrossRefGoogle Scholar
  73. Maas EV, Grattan SR (1999) Crop yields as affected by salinity. In: Skaggs RW, van Schilfgaarde J (eds) Agricultural drainage. ASA-CSSA-SSSA, Madison, pp 55–108Google Scholar
  74. Maas EV, Hoffman GJ (1977) Crop salt tolerance – current assessment. J Irrig Drain Div 103:115–134Google Scholar
  75. Mace JE, Amrhein C, Oster JD (1999) Comparison of gypsum and sulfuric acid for sodic soil reclamation. Arid Soil Res Rehabil 13:171–188CrossRefGoogle Scholar
  76. Malik KA, Aslam Z, Naqvi M (1986) Kallar grass: a plant for saline land. Nuclear Institute of Agriculture and Biology, Faisalabad, PakistanGoogle Scholar
  77. Manousaki E, Kalogerakis N (2011) Halophytes – an emerging trend in phytoremediation. Int J Phytorem 13:959–969CrossRefGoogle Scholar
  78. Marcum KB, Murdoch CL (1994) Salinity tolerance mechanisms of six C4turf grasses. J Am Soc Hortic Sci 119:779–784CrossRefGoogle Scholar
  79. Marion GM, Babcock KL (1976) Predicting specific conductance and salt concentration in dilute aqueous solutions. Soil Sci 122:181–187CrossRefGoogle Scholar
  80. McGrath SP, Zhao FJ, LombiE (2002) Phytoremediation of metals, metalloids, and radionuclides. Adv Agron 75:1–56CrossRefGoogle Scholar
  81. Minhas PS, Dubey SK, Sharma DR (2007) Effects on soil and paddy–wheat crops irrigated with waters containing residual alkalinity. Soil Use Manag 23:254–261.  https://doi.org/10.1111/j.1475-2743.2007.00090.xCrossRefGoogle Scholar
  82. Mishra A, Sharma SD, Khan GH (2002) Rehabilitation of degraded sodic lands during a decade of Dalbergia sissoo plantation in Sultanpur district of Uttar Pradesh, India. Land Degrad Dev 13:375–386CrossRefGoogle Scholar
  83. Mubarak AR, Nortcliff S (2010) Calcium carbonate solubilization through H proton release from some legumes grown in calcareous saline-sodic soils. Land Degrad Dev 21:24–31CrossRefGoogle Scholar
  84. Munns R, Tester M (2008) Mechanisms of salinity tolerance. Annu Rev Plant Biol 59:651–681CrossRefGoogle Scholar
  85. Naidu R, Rengasamy P (1993) Ion interactions and constraints to plant nutrition in Australian sodic soils. Aust J Soil Res 31:801–819CrossRefGoogle Scholar
  86. Okeke BC, Giblin T, Frankenberger WT Jr (2002) Reduction of perchlorate and nitrate by salt tolerant bacteria. Environ Pollut 118:a357–a363CrossRefGoogle Scholar
  87. Oren A (1999) Bioenergetic aspects of halophilism. Microbiol Mol Biol Rev 63:334–348Google Scholar
  88. Oster JD (1982) Gypsum usage in irrigated agriculture: a review. Fertil Res 3:73–89CrossRefGoogle Scholar
  89. Oster JD, Wichelns D (2003) Economic and agronomic strategies to achieve sustainable irrigation. Irrig Sci 22:107–120CrossRefGoogle Scholar
  90. Oster JD, Shainberg J, Abrol JP (1999) Reclamation of salt-affected soils. In: Skaggs RW, Van Schilfgaarde G (eds) Agricultural drainage, Agronomy monograph no. 38. Agronomy Society of America, Madison, pp 659–694Google Scholar
  91. Overstreet R, Martin JC, Schulz RK, McCutcheon OD (1955) Reclamation of an alkali soil of the Hacienda series. Hilgardia 24:53–68CrossRefGoogle Scholar
  92. Parthasarathy M, Pemaiah B, Natesan R, Padmavathy SR, Pachiappan J (2015) Real-time mapping of salt glands on the leaf surface of Cynodon dactylon L. using scanning electrochemical microscopy. Bioelectrochemistry 101:159–164CrossRefGoogle Scholar
  93. Paul EA, Clark FE (1996) Soil microbiology and biochemistry. Academic, San DiegoGoogle Scholar
  94. Pilon-Smits E (2005) Phytoremediation. Annu Rev Plant Biol 56:15–39CrossRefGoogle Scholar
  95. Pitman MG, Läuchli A (2002) Global impact of salinity and agricultural ecosystems. In: Läuchli A, Lüttge U (eds) Salinity: environment–plants–molecules. Kluwer Academic, Dordrecht, pp 3–20Google Scholar
  96. Qadir M, Oster JD (2002) Vegetative bioremediation of calcareous sodic soils: history, mechanisms, and evaluation. Irrig Sci 21:91–101CrossRefGoogle Scholar
  97. Qadir M, Schubert S (2002) Degradation processes and nutrient constraints in sodic soils. Land Degrad Dev 13:275–294CrossRefGoogle Scholar
  98. Qadir M, Qureshi RH, Ahmad N (1996a) Reclamation of a saline-sodic soil by gypsum and Leptochloa fusca. Geoderma 74(3–4):207–217CrossRefGoogle Scholar
  99. Qadir M, Qureshi RH, Ahmad N, Ilyas M (1996b) Salt-tolerant forage cultivation on a saline-sodic field for biomass production and soil reclamation. Land Degrad Dev 7:11–18CrossRefGoogle Scholar
  100. Qadir M, Qureshi RH, Ahmad N (1997) Nutrient availability in a calcareous saline-sodic soil during vegetative bioremediation. Arid Soil Res Rehabil 11:343–352CrossRefGoogle Scholar
  101. Qadir M, Ghafoor A, Murtaza G (2000) Amelioration strategies for saline soils: a review. Land Degrad Dev 11:501–521.  https://doi.org/10.1002/1099-145x(200011/12)11:6<501::aid-ldr405>3.0.co;2-sCrossRefGoogle Scholar
  102. Qadir M, Schubert S, Ghafoor A, Murtaza G (2001) Amelioration strategies for sodic soils: a review. Land Degrad Dev 12:357–386CrossRefGoogle Scholar
  103. Qadir M, Qureshi RH, Ahmad N (2002) Amelioration of calcareous saline–sodic soils through phytoremediation and chemical strategies. Soil Use Manag 18:381–385CrossRefGoogle Scholar
  104. Qadir M, Noble AD, Oster JD, Schubert S, Ghafoor A (2005) Driving forces for sodium removal during phytoremediation of calcareous sodic and saline-sodic soils: a review. Soil Use Manag 21:173–180CrossRefGoogle Scholar
  105. Qadir M, Noble AD, Schubert S, Thomas RJ, Arslan A (2006) Sodicity induced land degradation and its sustainable management: problems and prospects. Land Degrad Dev 17:661–676CrossRefGoogle Scholar
  106. Qadir M, Oster JD, Schubert S, Noble AD, Sahrawat KL (2007) Phytoremediation of sodic and saline-sodic soils. Advances in agronomy, vol 96. Elsevier, Amsterdam, pp 197–247Google Scholar
  107. Qadir M, Tubeileh A, Akhtar J, Larbi A, Minhas PS, Khan MA (2008) Productivity enhancement of salt-affected environments through crop diversification. Land Degrad Dev 19:429–453CrossRefGoogle Scholar
  108. Rabhi M, Hafsi C, Lakhdar A, Barhoumi Z, Hamrouni MH, Abdelly C, Smauoi A (2009) Evaluation of the capacity of three halophytes to desalinize their rhizosphere as grown on saline soils under non leaching conditions. Afr J Ecol 47:463–468CrossRefGoogle Scholar
  109. Rabhi M, Ferchichi S, Jouini J, Hamrouni MH, Koyro HW, Ranieri A, Smaoui A (2010) Phytodesalination of a salt-affected soil with the halophyte Sesuvium portulacastrum L. to arrange in advance the requirements for the successful growth of a glycophytic crop. Bioresour Technol 101(17):6822–6828CrossRefGoogle Scholar
  110. Rasouli F, Kiani Pouya A, Karimian N (2013) Wheat yield and physico-chemical properties of a sodic soil from semi-arid area of Iran as affected by applied gypsum. Geoderma 193–194:246–255.  https://doi.org/10.1016/j.geoderma.2012.10.001CrossRefGoogle Scholar
  111. Ravindran KC, Venkatesan K, Balakrishnan V, Chellappan KP, Balasubramanian T (2007) Restoration of saline land by halophytes for Indian soils. Soil Biol Biochem 39(10):2661–2664CrossRefGoogle Scholar
  112. Rengasamy P (2006) World salinization with emphasis on Australia. J Exp Bot 57:1017–1023CrossRefGoogle Scholar
  113. Rich SM, Ludwig M, Colmer TD (2008) Photosynthesis in aquatic adventitious roots of the halophytic stem succulent Tecticornia pergranulata (formerly Halosarcia pergranulata). Plant Cell Environ 31:1007–1016CrossRefGoogle Scholar
  114. Ridley AM, Christy B, Dunin FX, Haines PJ, Wilson KF, Ellington A (2001) Lucerne in crop rotations on the Riverina Plains. 1. The soil water balance. Crop Past Sci 52:263–277CrossRefGoogle Scholar
  115. Robbins CW (1986a) Sodic calcareous soil reclamation as affected by different amendments and crops. Agron J 78:916–920CrossRefGoogle Scholar
  116. Robbins CW (1986b) Carbon dioxide partial pressure in lysimeter soils. Agron J 78:151–158CrossRefGoogle Scholar
  117. Robson DB (2003) Phytoremediation of hydrocarbon contaminated soil using plants adapted to the western Canadian climate. PhD thesis, University of Saskatchewan, Saskatchewan, CanadaGoogle Scholar
  118. Saboora A, Kiarostami K, Behroozbayati F, Hashemi SH (2006) Salinity (NaCl) tolerance of wheat genotypes at germination and early seedling growth. Pak J Biol Sci 9(11):2009–2021CrossRefGoogle Scholar
  119. Salt DE, Smith RD, Raskin I (1998) Phytoremediation. Annu Rev Plant Physiol Plant Mol Biol 49:643–668CrossRefGoogle Scholar
  120. Sarraf M (2004) Assessing the costs of environmental degradation in the Middle East and North Africa countries. Environment Strategy Notes 9, Environment Department World Bank, Washington, DCGoogle Scholar
  121. Setia R, Marschner P, Baldock J, Chittleborough D, Smith P, Smith J (2011) Salinity effects on carbon mineralization in soils of varying texture. Soil Biol Biochem 43:1908–1916CrossRefGoogle Scholar
  122. Shainberg I, Letey J (1984) Response of soils to sodic and saline conditions. Hilgardia 52:1–57CrossRefGoogle Scholar
  123. Shainberg I, Sumner ME, Miller WP, Farina MPW, Pavan MA, Fey MV (1989) Use of gypsum on soils: a review. Adv Soil Sci 9:1–111Google Scholar
  124. Shannon MC (1997) Adaptation of plants to salinity. Adv Agron 60:76–120Google Scholar
  125. Shekhawat VPS, Kumar A, Neumann KH (2006) Bio-reclamation of secondary salinized soils using halophytes. In: Öztürk M, Waisel Y, Khan MA, Görk G (eds) Biosaline agriculture and salinity tolerance in plants. Birkhäuser, Basel, pp 147–154.  https://doi.org/10.1007/3-7643-7610-4-16CrossRefGoogle Scholar
  126. Shelef O, Gross A, Rachmilevitch S (2012) The use of Bassia indica for salt phytoremediation in constructed wetlands. Water Res 46:3967–3976.  https://doi.org/10.1016/j.watres.2012.05.020CrossRefGoogle Scholar
  127. Siciliano SD, Germida JJ (1998) Biolog analysis and fatty acid methyl ester profiles indicate that pseudomonad inoculants that promote phytoremediation alter the rootassociated microbial community of Bromus biebersteinii. Soil Biol Biochem 30:1717–1723CrossRefGoogle Scholar
  128. Singh OV, Jain RK (2003) Phytoremediation of toxic aromatic pollutants from soil. Appl Microbiol Biotechnol 63:128–135CrossRefGoogle Scholar
  129. Singh MV, Singh KN (1989) Reclamation techniques for improvement of sodic soils and crop yield. Indian J Agric Sci 59:495–500Google Scholar
  130. Singh K, Chauhan HS, Rajput DK, Singh DV (1989) Report of a 60 month study on litter production, changes in soil chemical properties and productivity under Poplar (P. deltoides) and Eucalyptus (E. hybrid) interplanted with aromatic grasses. Agrofor Syst 9(1):37–45CrossRefGoogle Scholar
  131. Soil Science Society of America (2006) Internet glossary of soil science terms. Available at: http://www.soils.org/sssagloss/
  132. Suarez DL (2001) Sodic soil reclamation: modelling and field study. Aust J Soil Res 39:1225–1246CrossRefGoogle Scholar
  133. Suer P, Andersson-Sköld Y (2011) Biofuel or excavation? – Life cycle assessment (LCA) of soil remediation options. Biomass Bioenergy 35:969–981CrossRefGoogle Scholar
  134. Sumner ME (1993) Sodic soils: new perspectives. Aust J Soil Res 31:683–750CrossRefGoogle Scholar
  135. Sumner ME, Rengasamy P, Naidu R (1998) Sodic soils: a reappraisal. In: Sumner ME, Naidu R (eds) Sodic soil: distribution, management and environmental consequences. Oxford University Press, New York, pp 3–17Google Scholar
  136. Susarla S, Medina VF, McCutcheon SC (2002) Phytoremediation: an ecological solution to organic chemical contamination. Ecol Eng 18:647–658CrossRefGoogle Scholar
  137. Szabolcs I (1994) Soils and salinization. In: Pessarakli M (ed) Handbook of plant and crop stress, 1st edn. Marcel Dekker, New York, pp 3–11Google Scholar
  138. Tanji KK (1990) Nature and extent of agricultural salinity. In: Tanji KK (ed) Agricultural salinity assessment and management, Manuals and reports on engineering practices no. 71. American Society of Civil Engineers, New York, pp 1–17Google Scholar
  139. Teakle NL, Bowman S, Barrett-Lennard EG, Real D, Colmer TD (2012) Comparisons of annual pasture legumes in growth, ion regulation and root porosity demonstrate that Melilotus siculus has exceptional tolerance to combinations of salinity and waterlogging. Environ Exp Bot 77:175–184CrossRefGoogle Scholar
  140. Tester M, Davenport R (2003) Na+ tolerance and Na+ transport in higher plants. Ann Bot 91:503–527CrossRefGoogle Scholar
  141. Tipirdamaz R, Gagneul D, Duhazé C, Aïnouche A, Monnier C, Özkum D, Larher F (2006) Clustering of halophytes from an inland salt marsh in Turkey according to their ability to accumulate sodium and nitrogenous osmolytes. Environ Exp Bot 57:139–153.  https://doi.org/10.1016/j.envexpbot.2005.05.007CrossRefGoogle Scholar
  142. U.S. Salinity Laboratory Staff (1954) Diagnosis and improvement of saline and alkali soils, USDA handbook no. 60. U.S. Government Printing Office, Washington, DCGoogle Scholar
  143. US-EPA [United States-Environmental Protection Agency] (2000) Introduction to Phytoremediation. Office of Research & Development (EPA), Washington, DCGoogle Scholar
  144. Van-Camp L, Bujarrabal B, Gentile A-R, Jones RJA, Montanarella L,Olazabal C, Selvaradjou S-K (2004) Reports of the Technical Working Groups established under the thematic strategy for soil protection EUR 21319 EN/2, 872 pp Office for Official Publications of the European Communities, Luxembourg:192Google Scholar
  145. van der Moezel PG, Watson LE, Pearce-Pinto GVN, Bell DT (1988) The response of six Eucalyptus species and Casuarina obesa to the combined effect of salinity and water logging. Aust J Plant Physiol 15:465–474Google Scholar
  146. Walker DJ, Lutts S, Sánchez-García M, Correal E (2013) Atriplex halimus L.: its biology and uses. J Arid Environ 100–101:111–121.  https://doi.org/10.1016/j.jaridenv.2013.09.004CrossRefGoogle Scholar
  147. Wang W, Vinocur B, Altman A (2003) Plant responses to drought, salinity and extreme temperatures: towards genetic engineering for stress tolerance. Planta 218:1–14.  https://doi.org/10.1007/s00425-003-1105-5CrossRefGoogle Scholar
  148. Wang YC, Ko CH, Chang FC, Chen PY, Liu TF, Sheu YS, Teng CJ (2011) Bioenergy production potential for aboveground biomass from a subtropical constructed wetland. Biomass Bioenergy 35(1):50–58CrossRefGoogle Scholar
  149. Wicke B, Smeets E, Dornburg V, Vashev B, Gaiser T, Turkenburg W, Faaij A (2011) The global technical and economic potential of bioenergy from salt-affected soils. Energy Environ Sci 4:2669–2681.  https://doi.org/10.1039/c1ee01029hCrossRefGoogle Scholar
  150. Wong VN, Greene RSB, Dalal RC, Murphy BW (2010) Soil carbon dynamics in saline and sodic soils: a review. Soil Use Manag 26(1):2–11CrossRefGoogle Scholar
  151. Wright DA, Wellbourn P (2002) Environmental toxicology, vol 11. Cambridge University Press, CambridgeCrossRefGoogle Scholar
  152. Wu SS (2009) Enhanced phytoremediation of salt-impacted soils using plant growthpromoting rhizobacteria (PGPR). MSc thesis. University of Waterloo, Waterloo, ONGoogle Scholar
  153. Wu YQ, Taliaferro CM, Martin DL, Goad CL, Anderson JA (2006) Genetic variability and relationships for seed yield and its components in Chinese Cynodon accessions. Field Crop Res 98:245–252CrossRefGoogle Scholar
  154. Wursten JL, Powers WL (1934) Reclamation of virgin black alkali soils. J Am Soc Agron 26:752–762CrossRefGoogle Scholar
  155. Yensen NP, Biel KY (2006) Soil remediation via salt-conduction and the hypotheses of halosynthesis and photoprotection ecophysiology of high salinity tolerant plants. In: Khan MA, Weber DJ (eds) Tasks for vegetation science 34, vol 40. Springer, Dordrecht, pp 313–344.  https://doi.org/10.1007/1-4020-4018-0_21CrossRefGoogle Scholar
  156. Zhuang X, Chen J, Shim H, Bai Z (2007) New advances in plant growth-promoting rhizobacteria for bioremediation. Environ Int 33:406–413CrossRefGoogle Scholar

Copyright information

© Springer Nature Singapore Pte Ltd. 2020

Authors and Affiliations

  • Neerja Srivastava
    • 1
  1. 1.Department of BiochemistryIBSBT, CSJM UniversityKanpurIndia

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