Evaluation Effect of Different Levels of Zinc and Manganese Nano-Chelate on Quantitative and Qualitative Traits of Cowpea (Vigna unguiculata L.)
Subject Areas : Journal of Crop Nutrition SciencePoran Alasvand 1 , Alireza Shokuhfar 2
1 - Department of Agronomy, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran.
2 - Department of Agronomy, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran.
Keywords: Protein, Nutrition, yield, Micro elements,
Abstract :
Nano fertilizers are new products which contain readily available nutrients in the nano scale range and are preferred largely due to their efficiency. This research was conducted to assessment the effect of nano chelated of micro nutrient on agronomic traits of Cowpea via factorial experiment based on randomized complete block design with four replications during 2016 seasonal year. The treatments included zinc nano chelated (5, 10 and 10 kg.ha-1) and manganese nano chelated (0, 4 and 8 kg.ha-1). The results of analysis of variance showed that effect of nano chelated of zinc and manganese had a significant effect on plant height, pod length, yield and its components also interaction effect of treatments on number of pods per m2, seed yield, biological yield and protein yield was significant. Result of mean comparison revealed the highest plant height (154.54 cm), pod length (13.14 cm), number of pods per m2 (116.47), number of pods per plant (14.52), number of seeds per pod (11.36), seed weight (23.03) and seed yield (210.08 g.m-2) belonged to 10 kg.ha-1 nano zinc chelate zinc treatment and the lowest amount of mentioned traits belonged to control (no fertilizer). Between different level of nano manganese chelate the highest seed yield and its components belonged to 8 kg.ha-1 treatment. According result of interaction of treatments indicated the highest number of pods per m2 (131.6), seed yield (244.7 g.m-2), biological yield (544.5 g.m-2) and protein yield (76.8 g.m-2) belonged to 10 kg.ha-1 nano zinc chelate and 8 kg.ha-1 nano manganese chelate and the lowest amount of mentioned traits belonged to control (no fertilizer). Finally based on result of this research use 10 kg.ha-1 nano zinc chelate and 8 kg.ha-1 nano manganese chelate improve quantitative and qualitative yield of cowpea and can be advised to farmers.
Asodeh, Z. 2009. Study the effect of manganese Nano chelate on seed yield and physiological traits of mungbean. MSc. Theses. Islamic Azad University. Tehran. Iran. 117 pp. (Abstract in English)
Bakhash-Kelarestaghi, K., H. Madani, M. Bazoobani. and M. Asadi. 2007. Optimizing of zinc quantity and application method on bread wheat (Triticum aestivum L.) in Bam region of Iran. Proc. Zinc Crops Conf. Istanbul. Turkey.
Barker, A. V. and D. J. Pilbeam. 2006. Handbook of Plant Nutrition. CRC Press. ISBN: 9780824759049.
Batsmanova, L. M., L. M. Gonchar, N .Y. Taran. and A. A. Okanenko. 2013. Using a colloidal solution of metal nanoparticles as micronutrient fertilizer for cereals. Proc. Intl. Conf. Nano-materials: Applications and Properties. pp: 11-14.
Cakmak, I. 2000. Possible roles of zinc in protecting plant cells from damage by reactive oxygen species. J. New Phytol. 146: 185-205.
De Rosa, M. C., C. Monreal, M. Schnitzer, R. Walsh. and Y. Sultan. 2010. Nanotechnology in fertilizers. J. Nature Nano-Tech. 5(2): 91-91.
Doi: 10.1038/nnano.2010.2.
Farnia, A. and M. M. Omidi. 2015. Effect of Nano-Zinc chelate and Nano-bio fertilizer on yield and yield components of Maize (Zea Mays L.), under water stress condition. Ind. J. Natural Sci. 5(29): 4614-4624.
Fatahe, R. 2006. Study the effects of integrated application of micronutrient (zinc Nano chelate) on mungbean yield. 18th Cong. Soil Sci. pp: 18-21.
Foadi, O. 2014. Assessment effect of different level of zinc on yield of cowpea. 13th National Iranian Crop Sci. Cong. Karaj. Iran. (Abstract in English)
Gardner, F. P., R. B. Pearce. and R. L. Mitchell. 1985. Physiology of crop plants. Ames, IA: Iowa State Univ. Press. USA. 121 pp.
Ghasemi-Fasaei, R. and A. Ronaghi. 2008. Interaction of iron with copper, zinc, and manganese in wheat as affected by iron and manganese in a calcareous soil. J. Plant Nutrition. 31(5): 839-848. Doi: 10.1080/01904160802043148.
Hansch, R. and R. R. Mendel. 2009. Physiological functions of mineral micronutrients (Cu, Zn, Mn, Fe, Ni, Mo, B, Cl). J. Current Opinion in Plant Biol. 12(3): 259-266. Doi: 10.1016/j.pbi.2009.05.006.
Harssine, M. G., H. Habibe, G. H. Talaiy. 2014. Study the effects of iron Nano chelate fertilizers foliar application on yield and its components of wheat. J. Agric. Adv. 3(4): 95-102.
Hoseynabadi, A, M. Golvi. and M. Heydari. 2006. Study the effects of spraying iron, zinc and manganese on the properties and quality of wheat in Sistan region. The New Findings Agric. 1(2): 11-20. (Abstract in English)
Jamshidi, M., A. R. Danesh Shahraki. and S. M. Hashemi Jozei. 2016. The effect of foliar spray of manganese and zinc elements on grain yield and yield components of red bean seeds under drought stress conditions. Iranian J. Cereal Res. 7(2): 167-174. (Abstract in English)
Janmohamadi, M., T. Amanzadeh, N. Sabaghnia. and Sh. Dashti. 2016a. Impact of foliar application of Nano micronutrient fertilizers and titanium dioxide nanoparticles on the growth and yield components of barley under supplemental irrigation. J. Acta Agric. Slovenica. 107(2): 265-276.
Janmohammadi, M., N. Sabaghnia, Sh. Dashti. and M. Nouraein. 2016b. Investigation of foliar application of Nano-micronutrient fertilizers and Nano-titanium dioxide on some traits of barley. J. Biologija. 62(2): 148–156.
Jafardoukht, R., M. Mousavi Nick, A. Mehraban. and M. Basiri. 2015. Effect of drought stress and foliar spray of micronutrients on physiological characteristics and nutrient uptake in Mungbean. J. Crop Prod. 8(1): 121-141.
Jalilshesh-Bahre, M. and M. Movahedi Dhnavi. 2012. Effect of zinc and iron application on soybean seed vigor grown under drought stress. E. J. Crop Prod. 5: 19-35. (Abstract in English)
Jokar, L., A. Ronaghi, N. Karimian. and R. Ghasemi-Fasaei. 2015. Effects of different Fe levels from Fe-Nano-chelate and Fe-EDDHA sources on growth and some nutrients concentrations in cowpea in a calcareous soil. J. Sci. Tech. Greenhouse Culture. 6(22): 9-19. (Abstract in English)
Kabata-Pendias, A. and H. Pendias, 1999. Biogeochemistry of Trace Elements, Second Edition. Wyd. Nauk. PWN. Warsaw.
Linn, J. G. and N. P. Martin. 1999. Forage quality tests and interpretation. The College of Agricultural. Food and Environmental Sciences. University of Minnesota Press, USA.
Mabhot, P. 2017. Effect of different level of Nano-chelate zinc on quantitative traits and seed yield of cowpea. 5th National Conf. Iranian Soc. Plant. Physiol. Cong. Zanjan University. Zanjan. Iran. (Abstract in English)
Malakooti, M. J. and S. J. Tabataei. 1998. Plant feeding by foliar application. Agri. Educate. Pub. Karaj. Iran.
Mandeh, M., M. Omidi. and M. Rahaie. 2012. In vitro influences of TiO2 nanoparticles on barley (Hordeum vulgare L.) tissue culture. J. Biol. Trace Element Res. 150(1-3): 376-380. Doi: 10.1007/s12011-012-9480-z.
Marschner, H. 1986. Mineral nutrition of higher plants. Academic Press Inc. USA. pp: 269-369.
Marschner, H. 1995. Mineral nutrition of higher plants. 2nd Ed. Academic Press. London. UK.
Marschner, H. 1993. Zinc in soil and plant, Robon, A. D. (Ed.), Zinc in soil and plants, Drodrcht, the Netherlands. Kluwer Academic Pub. pp: 55-77.
Marschner, H. 2012. Mineral Nutrition of Higher Plants. Academic Press Limited Harcourt Brace and Company. Pub. London. UK. pp: 347–364. ISBN: 9780123849052.
Mir, S., A. R. Sirousmehr. and E. Shirmohammadi. 2015. Effect of Nano and biological fertilizers on carbohydrate and chlorophyll content of forage sorghum (Speed feed hybrid). Intl. J. Bio-Sci. 6(4): 157-164.
Moallim, A. H. and H. R. Eshqizade. 2007. Application of bio-fertilizers: advantages and limitations. 2th Natl. Cong. Ecol. Agric. (Abstract in English)
Mosanna, R. and B. E. Khalilvand. 2015. Morpho-physiological response of maize (Zea mays L.) to zinc Nano-chelate foliar and soil application at different growth stages. J. New Biol. Rep. 4: 46–50.
Ojeda-Barrios, D. L., E. Perea-Portillo, O. A. Hernandez-Rodriguez, J. Martinez-Tellez, J. Abadia. and L. Lombardini. 2014. Foliar fertilization with zinc in pecan trees. J. Hort. Sci. 49: 562–566.
Naderi, M. R. and A. Danesh-Shahraki. 2013. Nano fertilizers and their roles in sustainable agriculture. Intl. J. Agric. Crop Sci. 5(19): 2229-2232.
Naderi, M., A. A. Danesh Shahraki. and R. Naderi. 2011. Application of Nano-Technology in the optimization of formulation of chemical fertilizers. Iran J. Nano-Tech. 12: 16–23.
Nair, R., S. H. Varghese, B. G. Nair, T. Maekawa, Y. Yoshida. and D. S. Kumar. 2010. Nano particulate material delivery to plants. J. Plant Sci. 179(3): 154-163.
Doi: 10.1016/j.plantsci.2010.04.012.
Padilla-Ramirez, K.S., K. A. Acosta-Gallegos, E. AcostaDiaz, N. Mayek-Perez. and J. D. Kelly. 2005. Partitioning and partitioning rate to seed yield in drought stressed and non-stressed dry bean genotypes. J. Bean Improvement Cooperative. 48: 153-153.
Prasad, T. N. V. K. V., P. Sudhakar, Y. Sreenivasulu, P. Latha, V. Munaswamya, K. RajaReddy, T. S. Sreeprasad, P. R. Sajanlal. and T. Pradeep. 2012. Effect of Nano-scale zinc oxide particles on the germination, growth and yield of peanut. J. Plant Nut. 35: 905-927.
Rameshaiah, G. N. and S. Jpallavi. 2015. Nano fertilizers and Nano sensors–an attempt for developing smart agriculture. Intl. J. Eng. Res. General Sci. 3(1): 314-320.
Saeedi-Aboueshaqi, Z. and Z. Yibwie. 2015. Study effect of zinc and iron on cowpea yield under water deficit conditions. J. Agric. Sci. 4(5): 133-143.
Saeedin, Z. 2016. Evaluate effect of different level of micronutrient on seed yield of cowpea. 14th National Iranian Crop Sci. Cong. Gilan University. Rasht. Iran. (Abstract in English)
Sarbandi, H. and H. Madani. 2014. Response yield and yield component of Chickpea to foliar application of micronutrients. Tech. J. Eng. Appl. Sci. 4(1): 18-22.
Scott, N. and H. Chen. 2003. Nano-scale science and engineering for agriculture and food systems. A Report Submitted to Cooperative State Research, Education and Extension Service. USDA. National Planning Workshop. Washington. USA.
Singh, N. B., N. Amist, K. Yadav, D. Singh, J. K. Pandey. and S. C. Singh. 2013. Zinc oxide Nano-particles as fertilizer for the germination, growth and metabolism of vegetable crops. J. Nano-Eng. Nano-Manuf. 3: 353–364.
Sheykhbegloo, N., A. Ghourt Tapeh, M. Baghestani. and B. Zand. 2009. Study of effect of zinc spraying on qualitative and quantitative yield of seed corn under water stress conditions. Electronic J. Agric. Plant Prod. 2(2): 6-16.
Shojaei, H. and H. Makarian. 2015. The effect foliar application zinc yield and yield component of Mungbean the drought stress. Iranian J. Field Crops Res. 12(4): 727-737. (Abstract in English)
Soleymani, A. and M. H. Shahrajabian. 2016. The effects of Fe, Mn and Zn foliar application on yield, ash and protein percentage of forage sorghum in climatic condition of Esfahan. Intl. J. Biol. 4(3): 92-97.
Song, U., M. Shin, G. Lee, J. Roh, Y. Kim. and E. J. Lee. 2013. Functional analysis of TiO2 nanoparticle toxicity in three plant species. J. Biol. Trace Element Res. 155(1): 93-103. Doi: 10.1007/s12011-013-9765-x.
Subramanian, K. S., A. Manikandan, M. Thirunavukkarasu. and C. Sharmila Rahale. 2015. Nano-fertilizers for balanced crop nutrition. In: M. Rai, C. Ribeiro, L. Mattoso, N. Duran (Eds.), Nano-Technologies in Food and Agriculture. Springer Intl. Pub. Switzerland. pp: 69–80.
Talaei, Gh. 2012. Effect of bio and chemical fertilizers on yield and yield components of Cumin. MSc Thesis. Shahed Univ. Tehran. Iran. (Abstract in English)
Tabatabaei, S. A. and A. Ranjbar. 2005. Effects of drought and sowing date on yield and water use efficiency of Nutrifeed Millet. 1th Cong. Effect of Environmental Drought Stress on Plants. Islamic Azad University. Takestan. Iran. pp: 109-120. (Abstract in English)
Vanluit, B. and R. Boxma. 1981. Quality check of iron chelates applied to ornamental shrubs on sphagnum peat. J. Hort. Sci. 56: 125-137.
Wiesner, M. R., G. V. Lowry, P. Alvarez, D. Dionysion. and P. Biswas. 2006. Assessing the risks of manufactured Nano-materials. J. Environ. Sci. Tech. 40: 4336-4345.
Zhang F., R. Wang, Q. Xiao, Y. Wang. and J. Zhang. 2006. Effects of slow/controlled-release fertilizer cemented and coated by Nano-materials on biology. II. Effects of slow/controlled-release fertilizer cemented and coated by Nano-materials on plants. J. Nano Sci. 11: 18-26.
Zlatimira, S. and S. Doncheva. 2002. The effect of zinc supply and succinate treatment on plant growth and mineral uptake in pea plant. Braz. J. Plant Physiol. 14(2): 111-116.