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The Application of Nanotechnology on Plant Nutrition and Agriculture: A Review

Year 2024, Volume: 7 Issue: 1, 100 - 112, 30.06.2024
https://doi.org/10.46876/ja.1384560

Abstract

Nanotechnology is one of the most versatile emerging technologies, based on producing and utilizing structures of materials possessing dimensions less than 100 nanometers. It is an interdisciplinary field, and its applications in various sciences and industries are expanding rapidly. Industrial agriculture is among the important experiencing swift advancements in nanotechnology. Industrial sectors have seen swift advancements in nanotechnology, which have led to significant advancements in various branches of this industry. In the field of soil science, nanotechnology is being used for effective plant nutrition management through the use of nanofertilizers, controlling soil-borne diseases with nanopesticides, remediation of salinity and removal of pollutants from soil using nanoparticles and porous nanosorbents, enhancing soil moisture retention capacity through superabsorbent nanomaterials, stabilizing erodible soils using nanosilicates and nanopolymers, and providing various chemical and biosensors for precise soil measurement. Despite all these capabilities, the application of nanotechnology in soil faces challenges such as uncertainty lack of knowledge regarding the environmental risks, complex behavior in heterogeneous soil environments, and expensive synthesis and analytical methods of nanomaterials.

Ethical Statement

Etik Beyanına gereksinim yoktur.

Supporting Institution

Yoktur.

Project Number

Yoktur.

Thanks

Yoktur.

References

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  • Askari, M., Talebi, S. M., & Shafieigavari, M. (2020). The impact of iron oxide nanoparticles on the growth and physiology of alfalfa (Medicago sativa L) inoculated with Rhizobium meliloti. Cell and Tissue, 11(1), 25-43.
  • Adhikari, T. (2013). Soil science and nanotechnology and plant nutrition. New India Agency.
  • Demirkiran, A. R., Fullen, M. A., & Williams, C. D. (2016). Comparative analysis of the physicochemical and oil adsorption characteristics of clinoptilolites from Turkey and the USA. Oxidation Communications, 39(1-II), 787-807.
  • Dhawi, F. J., Al-Khayri, M., & Hassan, E. (2009). Stationary magnetic influence of the field on elemental structure of date palm (Phoenix dactylifera L.). Research Journal of Farming and Biological Sciences, 5, 161-166.
  • Ditta, A. (2012). How helpful is nanotechnology in agriculture? Advances in Natural Sciences: Nanoscience and Nanotechnology, 3(3), 033002.
  • Hatefi, O., Jalalian, A., Padidar, M., & Fallahzade, J. (2016). Impact of nanoclay on movement erosive processes in sandy loam soil, Segzi Area (Isfahan, Iran). Journal of Environmental Science and Technology, 9(3), 296-300.
  • Hosseini, L. K., Mojaddam, M., & Babaei Nejad, T. (2019). Comparison of urea fertilizer with sulfur-coated urea: Impact of plant nutrients on the numeric and trait-related rice production. Journal of Plant Production Sciences, 9(1), 27-36.
  • Jatav, G. K., & De, N. (2013). Utilization of nanoscience in the plant-soil interaction. A Soil Research Periodical in Asia, 8(1), 176-184.
  • Karimi, A., Noshadi, M., & Ahmadzadeh, M. (2009). Investigation of the impacts of water-super absorbing polymer (igeta) on plantation, soil moisture, and watering frequency. Journal of Agricultural and Natural Resource Science and Technology, 12, 415-420.
  • Kianian, M. K. (2006). An inquiry into the impact of ecological factors on the growth and proliferation of plant varieties through complex data analysis, focusing on the case study of the eshtehards shour river area, Karaj, Iran. In Proceedings of the 1st international conference on water, ecosystems and sustainable development in arid and semi-arid zones (October 9-15, China).
  • Kianian, M. K. (2011). Research study on conservation and sustainable practices in dry environments, analyzing influential elements in salt-tolerant plants, and demonstration at Playa for data analysis relationships and additional carbon storage, Sirjan, Iran. In Proceedings of the 11th worldwide convention on information handling and information technologies (September 7-9, CEST, Greece).
  • Kianian, M. K. (2017). Research study on the impact of several moisture retention techniques on soil and growth characteristics in arid southern regions, specifically the Southern Desert Lands of Semnan city. (PhD Thesis, Gorgan University of Agricultural Sciences and Natural Resources).
  • Lu, C. M., Zhang, C. Y., Wu, J. Q., & Tao, M. X. (2002). Study of the impact of nanometer on sprouting and augmentation of Glycine max growth and its operation. Soybean Science, 21, 168-172.
  • Ma, M., Geiser-Lee, J., Deng, Y., & Kolmakov, A. (2010). Relationships among engineered nanoparticles (ENPs) and plant: Toxicity, aggregation absorption plant. Entire Environment Study, 408, 3053-3061.
  • Mazahernia, S., Starai, A., Fatut, A., & Clerk, A. (2010). Studying the influence of utilizing iron oxide (nano) and usual (mixed with sulfur granulated compost on iron) attention and development of Atial wheat plant. Journal of Farming Research in Iran, 6, 622-668.
  • Mukhopadhyay, S. S. (2014). Nanotechnology in agriculture: Prospects and constraints. Nanotechnology, Science and Applications, 63-71.
  • Musavi, S. R., & Rezaei, M. (2011). Nanoscience in farming and food manufacturing ecology. Journal of Applied Sciences, 1(10), 414-419.
  • Moaveni, P., & Kheiri, T. (2011). TiO₂ nanoparticles affected on maize (Zea mays L.). In Proceedings of the International Conference on Agricultural and Animal Science (Singapore, International Association of Computer Science and Information Technology Press, 22), 160-163.
  • Mousavi, S. Gh., Mirhadi, M. G., Siadat, S. A., Noor Mohammadi, Gh., & Darvish, F. (2009). Impact of water scarcity on the production of drought-resistant crop, another type of cereal grain, and water efficiency in fodder. Journal of New Science in Agriculture, 5(15), 101-114.
  • Naderi, M. R., & Abedi, A. (2012). Utilization of nanotechnology in farming and purification of environmental contaminants. Journal of Nanotechnology, 11(1), 18-26. [English abstract].
  • Naderi, M. R., & Danesh-Shahraki, A. (2011). Application of nanotechnology in the optimizing of formulation of chemical fertilizers. Iran Journal of Nanotechnology, 12, 16-23.
  • Nair, R. S., Varghese, H., Nair, B. G., Maekawa, T., Yoshida, Y., & Sakthi Kumar, D. (2010). Conveyance of nanoparticulate substances to vegetation. Botanical Science, 179, 154-163.
  • Nikbakht, J., Khande Rouyan, M., Tavakkoli, A., & Taheri, M. (2014). The impact of magnetic irrigation on germination and early growth characteristics of maize (Zea mays). Applied Field Crop Research, 27(105), 141-147.
  • Nazari, R., & Tag-Abadi Ebrahimi, M. (2005). Titanium dioxide (TiO₂) nanotechnology in the context of the environment. In Proceedings of the Fourth Biotechnology Event (June 14, Iran, Kerman).
  • Pandey, G. (2020). Agri-nanotechnology for sustainable agriculture. In Ecological and Practical Applications for Sustainable Agriculture (pp. 229-249).
  • Rai, M., Ribeiro, C., Mattoso, L., & Duran, N. (2015). Nanotechnology in food and farming. Verlag.
  • Reynolds, G. H. (2003). Nanotechnology and regulatory policy. Harvard Journal of Law and Technology, 17(1), 180-205.
  • Salehi, M., & Tamaskoni, F. (2008). Impact nanocid at seed treatment on germination and seedling growth wheat under salinity. In Proceedings of the First National Conference of Seed and Technology in Iran (p. 358). [English abstract].
  • Shah, V., & Belozerova, I. (2009). Impact of element nanoparticles on soil microorganisms and lettuce seed growth. Water, Air, and Soil Pollution, 197, 143-148.
  • Tarafdar, J. C., & Raliya, R. (2011). The nanotechnology. Scholarly Publisher.
  • Tarafdar, J. C., Sharma, S., & Raliya, R. (2013). The nanotechnology: Interdisciplinary science of applications. African Journal of Biotechnology, 12(3), 219-226.
  • Tsuji, K. (2001). Microencapsulation of pesticides and their improved handling safety. Journal of Microencapsulation, 18(2), 137-147.
  • Vasilevski, G. (2003). Perspectives of the application of biophysical methods in sustainable agriculture. Bulgarian Journal of Plant Physiology, 29(3), 179-186.
  • Wiswanathan, B. (2009). Nanomaterials. Alpha Science International Limited.
  • Zhang, P., Wang, H., Zhang, X., Xu, W., Li, Y., Li, Q., Wei, G., & Su, Z. (2015). Graphene film doped with silver nanoparticles: Assembly formation, structural characterizations, antibacterial ability, and biocompatibility. Biomaterials Science, 3, 852-860.
Year 2024, Volume: 7 Issue: 1, 100 - 112, 30.06.2024
https://doi.org/10.46876/ja.1384560

Abstract

Project Number

Yoktur.

References

  • Aladjadjiyan, A. (2007). Utilizing physical techniques to enhance plant growth in Bulgaria. Journal of Agriculture in Central Europe, 8, 369-380.
  • Askari, M., Talebi, S. M., & Shafieigavari, M. (2020). The impact of iron oxide nanoparticles on the growth and physiology of alfalfa (Medicago sativa L) inoculated with Rhizobium meliloti. Cell and Tissue, 11(1), 25-43.
  • Adhikari, T. (2013). Soil science and nanotechnology and plant nutrition. New India Agency.
  • Demirkiran, A. R., Fullen, M. A., & Williams, C. D. (2016). Comparative analysis of the physicochemical and oil adsorption characteristics of clinoptilolites from Turkey and the USA. Oxidation Communications, 39(1-II), 787-807.
  • Dhawi, F. J., Al-Khayri, M., & Hassan, E. (2009). Stationary magnetic influence of the field on elemental structure of date palm (Phoenix dactylifera L.). Research Journal of Farming and Biological Sciences, 5, 161-166.
  • Ditta, A. (2012). How helpful is nanotechnology in agriculture? Advances in Natural Sciences: Nanoscience and Nanotechnology, 3(3), 033002.
  • Hatefi, O., Jalalian, A., Padidar, M., & Fallahzade, J. (2016). Impact of nanoclay on movement erosive processes in sandy loam soil, Segzi Area (Isfahan, Iran). Journal of Environmental Science and Technology, 9(3), 296-300.
  • Hosseini, L. K., Mojaddam, M., & Babaei Nejad, T. (2019). Comparison of urea fertilizer with sulfur-coated urea: Impact of plant nutrients on the numeric and trait-related rice production. Journal of Plant Production Sciences, 9(1), 27-36.
  • Jatav, G. K., & De, N. (2013). Utilization of nanoscience in the plant-soil interaction. A Soil Research Periodical in Asia, 8(1), 176-184.
  • Karimi, A., Noshadi, M., & Ahmadzadeh, M. (2009). Investigation of the impacts of water-super absorbing polymer (igeta) on plantation, soil moisture, and watering frequency. Journal of Agricultural and Natural Resource Science and Technology, 12, 415-420.
  • Kianian, M. K. (2006). An inquiry into the impact of ecological factors on the growth and proliferation of plant varieties through complex data analysis, focusing on the case study of the eshtehards shour river area, Karaj, Iran. In Proceedings of the 1st international conference on water, ecosystems and sustainable development in arid and semi-arid zones (October 9-15, China).
  • Kianian, M. K. (2011). Research study on conservation and sustainable practices in dry environments, analyzing influential elements in salt-tolerant plants, and demonstration at Playa for data analysis relationships and additional carbon storage, Sirjan, Iran. In Proceedings of the 11th worldwide convention on information handling and information technologies (September 7-9, CEST, Greece).
  • Kianian, M. K. (2017). Research study on the impact of several moisture retention techniques on soil and growth characteristics in arid southern regions, specifically the Southern Desert Lands of Semnan city. (PhD Thesis, Gorgan University of Agricultural Sciences and Natural Resources).
  • Lu, C. M., Zhang, C. Y., Wu, J. Q., & Tao, M. X. (2002). Study of the impact of nanometer on sprouting and augmentation of Glycine max growth and its operation. Soybean Science, 21, 168-172.
  • Ma, M., Geiser-Lee, J., Deng, Y., & Kolmakov, A. (2010). Relationships among engineered nanoparticles (ENPs) and plant: Toxicity, aggregation absorption plant. Entire Environment Study, 408, 3053-3061.
  • Mazahernia, S., Starai, A., Fatut, A., & Clerk, A. (2010). Studying the influence of utilizing iron oxide (nano) and usual (mixed with sulfur granulated compost on iron) attention and development of Atial wheat plant. Journal of Farming Research in Iran, 6, 622-668.
  • Mukhopadhyay, S. S. (2014). Nanotechnology in agriculture: Prospects and constraints. Nanotechnology, Science and Applications, 63-71.
  • Musavi, S. R., & Rezaei, M. (2011). Nanoscience in farming and food manufacturing ecology. Journal of Applied Sciences, 1(10), 414-419.
  • Moaveni, P., & Kheiri, T. (2011). TiO₂ nanoparticles affected on maize (Zea mays L.). In Proceedings of the International Conference on Agricultural and Animal Science (Singapore, International Association of Computer Science and Information Technology Press, 22), 160-163.
  • Mousavi, S. Gh., Mirhadi, M. G., Siadat, S. A., Noor Mohammadi, Gh., & Darvish, F. (2009). Impact of water scarcity on the production of drought-resistant crop, another type of cereal grain, and water efficiency in fodder. Journal of New Science in Agriculture, 5(15), 101-114.
  • Naderi, M. R., & Abedi, A. (2012). Utilization of nanotechnology in farming and purification of environmental contaminants. Journal of Nanotechnology, 11(1), 18-26. [English abstract].
  • Naderi, M. R., & Danesh-Shahraki, A. (2011). Application of nanotechnology in the optimizing of formulation of chemical fertilizers. Iran Journal of Nanotechnology, 12, 16-23.
  • Nair, R. S., Varghese, H., Nair, B. G., Maekawa, T., Yoshida, Y., & Sakthi Kumar, D. (2010). Conveyance of nanoparticulate substances to vegetation. Botanical Science, 179, 154-163.
  • Nikbakht, J., Khande Rouyan, M., Tavakkoli, A., & Taheri, M. (2014). The impact of magnetic irrigation on germination and early growth characteristics of maize (Zea mays). Applied Field Crop Research, 27(105), 141-147.
  • Nazari, R., & Tag-Abadi Ebrahimi, M. (2005). Titanium dioxide (TiO₂) nanotechnology in the context of the environment. In Proceedings of the Fourth Biotechnology Event (June 14, Iran, Kerman).
  • Pandey, G. (2020). Agri-nanotechnology for sustainable agriculture. In Ecological and Practical Applications for Sustainable Agriculture (pp. 229-249).
  • Rai, M., Ribeiro, C., Mattoso, L., & Duran, N. (2015). Nanotechnology in food and farming. Verlag.
  • Reynolds, G. H. (2003). Nanotechnology and regulatory policy. Harvard Journal of Law and Technology, 17(1), 180-205.
  • Salehi, M., & Tamaskoni, F. (2008). Impact nanocid at seed treatment on germination and seedling growth wheat under salinity. In Proceedings of the First National Conference of Seed and Technology in Iran (p. 358). [English abstract].
  • Shah, V., & Belozerova, I. (2009). Impact of element nanoparticles on soil microorganisms and lettuce seed growth. Water, Air, and Soil Pollution, 197, 143-148.
  • Tarafdar, J. C., & Raliya, R. (2011). The nanotechnology. Scholarly Publisher.
  • Tarafdar, J. C., Sharma, S., & Raliya, R. (2013). The nanotechnology: Interdisciplinary science of applications. African Journal of Biotechnology, 12(3), 219-226.
  • Tsuji, K. (2001). Microencapsulation of pesticides and their improved handling safety. Journal of Microencapsulation, 18(2), 137-147.
  • Vasilevski, G. (2003). Perspectives of the application of biophysical methods in sustainable agriculture. Bulgarian Journal of Plant Physiology, 29(3), 179-186.
  • Wiswanathan, B. (2009). Nanomaterials. Alpha Science International Limited.
  • Zhang, P., Wang, H., Zhang, X., Xu, W., Li, Y., Li, Q., Wei, G., & Su, Z. (2015). Graphene film doped with silver nanoparticles: Assembly formation, structural characterizations, antibacterial ability, and biocompatibility. Biomaterials Science, 3, 852-860.
There are 36 citations in total.

Details

Primary Language English
Subjects Soil Sciences and Plant Nutrition (Other)
Journal Section Review Articles
Authors

Ali Rıza Demirkıran 0000-0002-0086-0137

Malake Sohrabi 0009-0005-8055-6379

Project Number Yoktur.
Publication Date June 30, 2024
Submission Date November 2, 2023
Acceptance Date May 23, 2024
Published in Issue Year 2024 Volume: 7 Issue: 1

Cite

APA Demirkıran, A. R., & Sohrabi, M. (2024). The Application of Nanotechnology on Plant Nutrition and Agriculture: A Review. Journal of Agriculture, 7(1), 100-112. https://doi.org/10.46876/ja.1384560