Evaluation Effect of Copper Foliar Application at Different Growth Stages of on Seed yield and Its Components of Cowpea (Vigna Sinensis L.)
Subject Areas : Journal of Crop Nutrition Science
Shahram Ashabi
1
,
Mohamad Reza Dadnia
2
1 - Msc. Graduated, Department of Agronomy, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran
2 - Assistant Professor, Department of Agronomy, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran.
Keywords: Nutrition, POD, harvest index, <i>Crop production, Pulse</i>,
Abstract :
BACKGROUND: Nutrients play a very important role in chemical, biochemical, physiological, metabolic, geochemical, biogeochemical, and enzymatic processes. OBJECTIVES: This research was done to assess the effect of different concentration and stage of foliar application of Copper on seed yield, yield components and harvest index of Cowpea. METHODS: This research was carried out via factorial experiment based on randomized complete blocks design with three replications along 2017 year. The treatments included different concentration of Copper foliar application (a1: none use of copper or control, a2: 150 gr.ha-1, a3: 300 gr.ha-1, a4: 450 gr.ha-1) and Copper foliar application at different growth stage (b1: apply at vegetative stage, b2: beginning of flowering stage, b3: beginning of pod formation). This experiment had 36 plots. RESULT: Result of analysis of variance revealed effect of different concentration and growth stage of foliar application of Copper on all measured traits was significant but interaction effect of treatments was not significant (instead number of pod per plant, seed yield and biologic yield). Mean comparison result of different concentration of foliar application of Copper indicated that maximum amount of number of pod per plant (14.83), number of seed per pod (11.96), seed weight (23.65 gr), seed yield (211.61 gr.m-2), biologic yield (509.19 gr.m-2), harvest index (41.55%) was noted for 300 gr.ha-1 Copper (Also it doesn’t have significant difference with 150 gr.ha-1 Copper) and minimum of those belonged to control treatment. As for Duncan classification made with respect to different growth stage of foliar application of Copper the highest amount of number of pod per plant (14.18), number of seed per pod (12.04), seed weight (23.41 gr), seed yield (206.01 gr.m-2), biologic yield (518.75 gr.m-2), harvest index (40.75%) belonged to vegetative stage and lowest ones was for beginning of pod formation. CONCLUSION: Finally based on result of current research according economic aspects use of 150 gr.ha-1 of copper foliar application in the vegetative stage at studied region is advised to producers.
Bar-Tal, A., U. Yermiyahu, J. Beraud, M. Keinan, R. Rosenberg, D. Zohar, V. Rosen. and P. Fine. 2004. Nitrogen, phosphorus, and potassium uptake by wheat and their distribution in soil following successive, annual compost applications. J. Environ. Quality. 33: 1855-1865.
Brennan, R. F. 1990. Effectiveness of some copper compounds applied as foliar sprays in alleviating copper-deficient soils of Western Australia. Australian J. Exp. Agri. 30: 687-691.
Bybordi, A. and G. Mamedov. 2010. Evaluation of application methods efficiency of zinc and iron for canola (Brassica napus L.). Notulae Scientia Biologicale. 2(1): 94-103.
Cavender, N., R. Atiyeh. and M. Knee. 2003. Vermicompost stimulates mycorrhizal colonization of roots of sorghum bicolor at the expense of plant growth. Pedobiologia. J. 47: 85-89.
Divyashree, K. S., S. S. Prakash, S. B. Yogananda. and N. Chandrappa. 2018. Seed yield and nutrient content of Mungbean and soil nutrient status as influenced by application of micronutrients mixture in a Alfisol. Intl. J. Current Microbiol. Appl. Sci. 7(9): 1706-1713.
Dobermann, A. and T. Fairhurst. 2000. Rice: Nutrient disorders and nutrient management IRRI. Potash and Phosphate Institute of Canada. 192 p.
El-Bassiony, A. M., Z. F. Fawzy, M. M. H. Abd El-Baky. and A. R. Mahmoud. 2010. Response of snap bean plants to mineral fertilizers and humic acid application. Res. J. Agri. Biomass Sci. 6: 169-175.
El-Habbasha, S. F., A. G. Ahmed. and M. H. Mohamed. 2012. Response of some chickpea varieties to compound foliar fertilizer under sandy soil conditions. J. Appl. Sci. Res. 8: 5177-5183.
Fan, M. S., F. J. Zhao, S. J. Fairweather-Tait, P. R. Poulton, S. J. Dunham. and S. P. McGrath. 2008. Evidence of decreasing mineral density in wheat grain over the last 160 years. J. Trace Elements Med. Biol. 22: 315-324.
Fernandez, J. C. and F. S. Henriques. 1991. Biochemical, physiological, and structural effects of excess copper in plants. Botanical Review. 57: 246-273.
Gardner, F. P., R. B. Pearce. and R. L. Mitchell. 1985. Physiology of crop plants. Ames, IA: Iowa State Univ. Press. USA. 121 pp.
Graham, R. D. 1975. Male sterility in wheat plants deficient in copper. Nature (London). UK. 254: 514-515.
Hosseinpour, A., Kh. Mahalleh, M. Roshdi. and N. Alinezhad. 2015. Evaluation of micronutrient application method and irrigation stopping on yield and yield component of grain Corn in Urmia (North-West Of Iran). Adv. Environ. Biol. 9(24): 431-437.
Lonergan, J. F. 1981. Distribution and movement of copper in plants. In: Copper in plants and soil. (Eds. J. F. Loneragan, A. D. Robson, R. D. Graham). Proc. Golden Jubilee Intl. Sym. May. Murdoch Univ. Perth. Western Australia. pp. 165-188.
Mohamed, A. E. and G. M. Taha. 2003. Levels of trace elements in different varieties of wheat determined by atomic absorption spectroscopy. Arabian J. Sci. Eng. 28: 163-171.
Rafi'i Shirvan, M. and M. Asghari Pour. 2008. Performance response of morphological characteristics of some mung bean genotypes to drought stress. 1St Intl. Conf. Water Crisis, Zabol, Zabol Univ. Hamoon Intl. Wetlands Research Institute. 61-50.
Ruiz-Garcia, Y. and E. Gomez-Plaza. 2013. Elicitors: A tool for improving fruit phenolic content. Agri. J. 3: 33-52.
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.
Shojaei, H. and H. Makarian. 2015. The effect foliar application zinc yield and its component of Mungbean. Iranian J. Field Crops Res. 12(4): 727-737. (Abstract in English)
Sujatha, M., B. Lingaraju, Y. Palled. and K. Ashalatha. 2008. Importance of integrated nutrient management practices in maize under rain fed condition. Karnataka J. Agri. Sci. 21: 334-338.
Sutradhar, A. K., D. E. Kaiser, C. J. Rosen. and J. A. Lamb. 2017. Copper for crop production. Nutr. Manag. FS-6790-B. Univ. Minn. Exten. pp. 1-6.
Welch, R. M. and R. O. Gramhan. 1999. A new paradigm for world agriculture: Meeting human needs: Productive, sustainable, nutritious. Field Crop Rev. 60(1-2): 1-10.