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How to Cite | Author Information | Publication History
International Journal of Earth & Environmental Sciences Volume 2 (2017), Article ID 2:IJEES-138, 6 pages
https://doi.org/10.15344/2456-351X/2017/138
Research Article
Changing Elemental Uptake of Roots and Leaves from Plants Grown on a Soil Variably Polluted by Crude Oil

Khadija Semhi1, Norbert Clauer2*, Nallusamy Sivakumar1, Waleed Al-Busaidi1, Khamis Al-Dhafri3 and Ahmed Al-Busaidi1

1Sultan Qaboos University, P.O. Box 36, Al-Khod 123, Muscat, Sultanate of Oman
2Ecole et Observatoire des Sciences de la Terre, Université de Strasbourg (UdS/CNRS), 1 rue Blessig, 67084 Strasbourg, France
3Faculty of Science, University of Malaya, 50603 Kuala Lumpur, Malaysia
Dr. Norbert Clauer, Ecole et Observatoire des Sciences de la Terre, Université de Strasbourg (UdS/CNRS), 1 rue Blessig, 67084 Strasbourg, France; E-mail: nclauer@unistra.fr
20 September 2017; 21 October 2017; 23 October 2017
Semhi K, Clauer N, Sivakumar N, Al-Busaidi W, Al-Dhafri K, et al. (2017) Changing Elemental Uptake of Roots and Leaves from Plants Grown on a Soil Variably Polluted by Crude Oil. Int J Earth Environ Sci 2: 138. doi: https://doi.org/10.15344/2456-351X/2017/138
© 2017 Semhi et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

References

  1. Obasi NA, Akubugwo EI, Kalu KM, Ugbogu AE, Okorie UC (2013) Toxicological assessment of various metals on selected edible leafy plants of umuka and ubahu dumpsites in okigwe of imo state, Nigeria. Journal of Experimental Biology and Agricultural Sciences 1: 441-453. View
  2. Adams RS, Ellis R (1960) Some physical and chemical changes in the soil brought about by saturation with natural gas. Soil Science Society of America Journal 24: 41-44.
  3. Uzoho B, Oti NN, Onweremadu EU (2004) Effect of crude oil pollution on maize growth and soil properties in Ihiagwa, Imo State, Nigeria. International Journal of Agriculture and Rural Development 5: 91-100. View
  4. Onuh MO, Madukwe DKK, Ohia GU (2008) Effects of poultry manure and cow dung on the physical and chemical properties of crude oil polluted soil. Science World Journal 3: 45-50. View
  5. Everett KR (1978) Some effects of oil on the physical and chemical characteristics of wet tundra soils. Arctic 31: 260-276. View
  6. Okonokhua BO, Ikhajiagbe B, Anoliefo GO, Emede TO (2007) The Effects of Spent Engine Oil on Soil Properties and Growth of Maize (Zeamays L.). Journal of Applied Sciences of Environmental Management 11: 147-152. View
  7. Vanloocke R, DeBorger R, Voets JP, Verstraete W (1975) Soil and groundwater contamination by oil spills; problems and remedies. International Journal of Environmental Studies 8: 99-111. View
  8. McGill WB (1980) Factors affecting oil degradation rates in soils. In: Disposal of Industrial and Oily Sludges by Land Cultivation. In: Shilesky DM (ed.), Resource Systems and Management Association, Northfield, New Jersey, 103-122.
  9. Baker JM (1971) Seasonal effects of oil pollution on salt marsh vegetation. OIKOS 22: 106-110. View
  10. Plice MJ (1948) Some effects of crude petroleum on soil fertility. Proceedings of the Soil Science Society of America 13:413-416.
  11. Baker JM (1970) The effects of oils on plants. Environmental Pollution 1: 27-44. View
  12. Schwendinger RB (1968) Reclamation of soil contaminated with oil. Journal de l’Institut Français du Pétrole 54: 182-197.
  13. Rowell MJ (1977) The effects of crude oil spill on soils. A review of literature. In: Toogood JA (ed.), The reclamation of agricultural soils after oil spills. Part I. Edmonton, Canada, p. 33.
  14. Ekpo MA, Ebeagwu CJ (2009) The effect of crude oil on microorganisms and dry matter of fluted pumpkin (Telfairia occidentalis). Scientific Research and Essay 4: 733-739. View
  15. Smith B, Stachowisk M, Volkenburgh E (1989) Cellular processes limiting leaf growth in plants under hypoxic root stress. Journal of Exploration Botany 40: 89-94. View
  16. Sparrow EB, Davenport CV, Gordon RC (1978) Response of microorganisms to hot crude oil spills on a subarctic Taiga soil. Arctic 31: 324-338. View
  17. Samuel J, Rouault R, Besnus Y (1985) Analyse multi-élémentaire standardisée des matériaux géologiques en spectrométrie d'émission par plasma à couplage inductif. Analysis 13: 312-317.
  18. Abosede EE (2013) Effect of crude oil pollution on some soil physical properties. Journal of Agriculture and Veterinary Science 6: 14-17. View
  19. Wang Y, Feng J, Lin Q, Lyu X, Wang X, Wang J (2013) Effects of crude oil contamination on soil physical and chemical properties in Momoge wetland of China. Chinese Geographical Science 23: 708-715. View
  20. Ziervogel K, D'souza N, Sweet J, Yan B, Passow U (2014) Natural oil slicks fuel surface water microbial activities in the northern Gulf of Mexico. Front Microbiology 5: 188. View
  21. Drever JI, Vance GF (1994) Role of soil organic acids in mineral weathering processes. Organic Acids in Geological Processes 138-161. View
  22. Njoku KL, Akinola MO, Oboh BO (2008) Does crude oil affect the ph, moisture and organic matter content of soils. Ecology, Environment and Conservation Paper 14: 731-736. View
  23. Banwart SA, Berg A, Beerling DJ (2009) Process-based modeling of silicate mineral weathering responses to increasing atmospheric CO2 and climate change. Global Biogeochemical Cycles 23: GB4013. View
  24. Shanker AK, Cervantes C, Loza-Tavera H, Avudainayagam S (2005) Chromium toxicity in plants. Environment International 31: 739-753. View
  25. Semhi K, Chaudhuri S, Clauer N (2006) Transfers of rare-earth elements from two types of soils to two species of plants. Geophysical Research Abstracts, ref-id: 1607-7962/gra/EGU06-A-01914, 1p.
  26. Semhi K, Chaudhuri S, Clauer N (2009) Fractionation of rare-earth elements in plants during an experimental growth in varied clay substrates. Applied Geochemistry 24: 447-453.27. Johannesson H, Lyons WB, Stetzenbach KJ, Byrne RH (1995) The solubility control of rare earth elements in natural terrestrial waters and the significance of PO43− and CO32− in limiting dissolved rare earth concentrations: A review of recent information. Aquatic Geochemistry 1: 157-173. View
  27. Johannesson H, Lyons WB, Stetzenbach KJ, Byrne RH (1995) The solubility control of rare earth elements in natural terrestrial waters and the significance of PO43− and CO32− in limiting dissolved rare earth concentrations: A review of recent information. Aquatic Geochemistry 1: 157-173. View
  28. Aide MT, Aide C (2012) Rare Earth Elements: Their importance in understanding soil genesis. Soil Science, 783876. View
  29. Ding S, Liang T, Zhang C, Wang LJ, Sun Q (2006) Accumulation and Fractionation of Rare Earth Elements in a Soil-Wheat System. Pedosphere 16: 82-90. View
  30. Ding S, Liang T, Zhang C, Juncai Y, Zhang Z, et al. (2005) Role of Ligands in Accumulation and Fractionation of Rare Earth Elements in Plants: Examples of Phosphate and Citrate. Biologic Trace Elemental Research 107: 73-86. View
  31. Ishikawa S, Wagatsuma T, Ikarashi T (1996) Comparative toxicity of Al3+, Yb3+, and La3+ to root-tip cells differing in tolerance to high Al3+ in terms of ionic potentials of dehydrated trivalent cations. Soil Science and Plant Nutrition 42: 613-625. View
  32. Quiquampoix H, Ratcliffe RG, Ratkovic S, Vucinic Z (1990) 1H and 31P NMR investigation of gadolinium uptake in maize roots. Journal of Inorganic Biochemistry 38: 265-275. View
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