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Manuscript ID : JCHR-598 Visit : 109 Page: 0 - 0

10.22034/jchr.2016.544137

Article Type: Original Research

The Effect of Phosphorus and Sulfur Nanofertilizers on the Growth and Nutrition of Ocimum basilicum in Response to Salt Stress

Subject Areas : Journal of Chemical Health Risks

Zarrin Taj Alipour 1

1 - Department of Soil Science, Damghan Branch, Islamic Azad University, Damghan, Iran

Received: 2016-03-12 Accepted : 2018-10-29 Published : 2016-03-12

Keywords: Salinity, phosphorus, basil, eutrophication,

Abstract :

Eutrophication is one of the most serious ecological threats to aquatic environments. It is defined as the enrichment of water bodies by organic matter or surface runoff containing nitrate and phosphate that directly control the growth of algae and other water plants. The use of nanofertilizers increases nutrient use efficiency and consequently reduces soil toxicity and minimizes the adverse effects of the over application of chemical fertilizers. This study was conducted in factorial form of a completely randomized design with four replications to evaluate the effect of phosphorus nanoparticles on the growth and nutrition of basil under salt stress. The first factor was three levels of salt stress, namely, 1, 3, and 6 dS m−1. The second factor was three levels of phosphorus fertilizer, namely, without phosphorus fertilizer (P1), ammonium phosphate (P2), and phosphorus nanoparticles (P3). Powdered elemental sulfur with a particle diameter of <0.6 mm at two rates, namely, 0% (S0) and 20% (S2), was utilized in the experiment. Physiological traits (i.e., chlorophyll content, P uptake, and proline content of leaves) were investigated in this study. Plant growth and P uptake decreased with the increase in salinity (P < 0.05). The application of phosphorus nanoparticles significantly increased P uptake in response to salt stress. Phosphorus nanoparticles significantly increased photosynthetic activity and plant weight in response to salt stress. Leaf proline content increased significantly in response to salt stress.

References:
  1. Sharpley A.N., Meisinger J.J., Power J.F., Suarez D.L., 1992. Root extraction of nutrients associated with long-term soil management. In: Stewart, B. Ed., Advances in Soil Science. 19,151ââ‚‌“217.
  2. Grattan S. R., Grieve C.M., 1994. Mineral nutrient acquisition and response by plants grown in saline environments. In: Pessarakli, M., Ed., Handbook of Plant and Crop Stress. Marcel Dekker, New York, pp. 203ââ‚‌“226.
  3. Champagnol F., 1979. Relationships between phosphate nutrition of plants and salt toxicity. Phosphorus Agri. 76, 35ââ‚‌“43.
  4. Art H.W., Eutrophication. In H.W. Art (Ed.). The Dictionary of Ecology and Environmental Science. 1rd ed., Holt and Paperbacks, New York, 1995.
  5. Rezaei R., Hoseini S.M., Shabanali Fami H., Safa L., 2010. Identification and Analysis of Barriers in the Development of Nanotechnology in Iran Agriculture Sector from the Researchers Point of View. Sci Technol Policy. 2(1), 17-26.
  6. Wurth B., 2007. Emissions of engineered and unintentionally produced nanoparticles to the soil. MSc Thesis. ETH Zurich.
  7. Naderi M.R., Danesh-Shahraki A., 2013. Nanofertilizers and their roles in sustainable agriculture. Int J Agri Crop Sci. 5(19), 2229ââ‚‌“2232.
  8. Fan Z.H., Lu J.G., 2003. Zinc Oxide Nanostructures: Synthesis and Properties. Science. 300, 1269-1280
  9. Derosa M.R., Monreal C., Schmitzer M., Walsh R., Sultan Y., 2010. Nanotechnology in Fertilizers. Nat Nanotechnol. 1, 193-225.
  10. Liu R., Lal R., 2014. Synthetic apatite nanoparticles as a phosphorus fertilizer for soybean (Glycine max). Scientific Reports. 4, 5686- 5696.
  11. Lin B.S., Shao-qi D., Chun l., 2004. Effect of TMS (nanostructured silicon dioxide) on growth of Changbai larch seedlings. J Forestry Res. 15, 138ââ‚‌“140.
  12. Walkley A., Black I.A., 1934. An examination of the Degtjareff method for determining organic carbon in soils: Effect of variations in digestion conditions and of inorganic soil constituents. Soil Sci. 63, 251-263.
  13. Bremer J.M. 1960. Determination of nitrogen in soil by Kjedahl method. J Agr Sci. 55,1-23.
  14. Arnon D.I., 1956. Photosyntesis by isolated chloroplast IV. General concept and comparison of three Photochemical reactions Biocbem. Biopbys Acta. 20, 499-461.
  15. Bates L.S., Waldern R.P., Teave I.D., 1973. Rapid determination of free proline for water stress studies. Plant and Soil. 39, 205-207.
  16. ïâ‚‌  Munns R., 2002. Comparative physiology of salt and water stress. Plant, Cell and Environment. 25, 239-250.
  17. Marschner H., 1995. Mineral nutrition of higher plant. Academic press.

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