تاثیر کاربرد نسبت نانو کلاتهای روی و آهن بر عملکرد و اجزای عملکرد ذرت (Zea mays L) در کشت مخلوط با لوبیا چشم بلبلی (Vigna unguiculata L)
الموضوعات : اکوفیزیولوژی گیاهان زراعیعلیرضا خالصی 1 , غلامرضا افشارمنش 2 , محمد حسن شیرزادی 3
1 - دانشجوی دکترای رشته زراعت، واحد جیرفت، دانشگاه آزاد اسلامی، جیرفت، ایران
2 - دانشیار مرکز تحقیقات، آموزش کشاورزی و منابع طبیعی جنوب استان کرمان، جیرفت، ایران
3 - استادیار گروه اگروتکنولوژی، واحد جیرفت، دانشگاه آزاد اسلامی، جیرفت، ایران
الکلمات المفتاحية: کشت مخلوط, ذرت, لوبیا چشم بلبلی, نانو کلات آهن, نانو کلات روی,
ملخص المقالة :
اثر کاربرد نسبت نانو کلات روی و آهن بر عملکرد و اجزای عملکرد ذرت در کشت مخلوط با لوبیا چشم بلبلی طی آزمایشی در قالب طرح بلوک های کامل تصادفی به صورت فاکتوریل و در سه تکرار در دو سال زراعی 98- 1397 و 99- 1398 درشهرستان رودبار از توابع جنوب استان کرمان بررسی گردید. تیمارها شامل کشت مخلوط ذرت و لوبیا در پنج سطح (100 درصد لوبیا، 75 درصد لوبیا + 25 درصد ذرت، 50 درصد لوبیا + 50 درصد ذرت، 25 درصد لوبیا + 75 درصد ذرت، و 100 درصد ذرت) و کاربرد نانوکلات آهن و روی در چهار سطح (نانو کلات آهن، نانو کلات روی، نانو کلات آهن + نانو کلات روی و شاهد) بودند. صفات اندازه گیری شده در این پژوهش شامل تعداد ردیف دانه در بلال، تعداد دانه در ردیف، تعداد دانه در بلال، وزن هزار دانه، عملکرد دانه و شاخص برداشت بودند. نتایج نشان داد اثر نسبت کاشت مخلوط ذرت و لوبیا بر روی تعداد دانه در بلال، وزن هزار دانه، شاخص برداشت و عملکرد دانه معنی دار بود. اثر متقابل نسبت های مختلف کاشت و نانو کلات بر تعداد دانه در بلال عملکرد دانه معنی دار و بر سایر صفات غیرمعنی دار بودند. بیشترین تعداد دانه در بلال (707.8عدد)، عملکرد دانه (12787 کیلوگرم در هکتار) و وزن هزار دانه ذرت (253 گرم) در کشت مخلوط با نسبت 25 درصد لوبیا + 75 درصد ذرت به دست آمد. همچنین، بیشترین شاخص برداشت (52 درصد) از کشت خالص به دست آمد. کاربرد همزمان نانو کلات آهن و روی باعث افـزایش ویژگی های کمّی و کیفی ذرت شد. بیشترین میزان پروتئین (22.3 درصد) در کشت مخلوط 25 درصد لوبیا و 75 درصد ذرت با کاربرد نانوکلات روی حاصل شد. بیشترین مقدار نسبت برابری زمین (کل) (2.12) در تیمار کشت مخلوط 75 درصد لوبیا+25 درصد ذرت و کاربرد آهن و روی با هم برآورد گردید و کمترین آن (1.57) مربوط به تیمار کشت مخلوط با نسبت 25 درصد لوبیا+75 درصد ذرت و کاربرد روی بود. در نهایت بالاترین عملکرد دانه ذرت 12993 کیلوگرم در هکتار از تیمار کشت مخلوط 75 درصد لوبیا+25 درصد ذرت و کاربرد آهن و روی بدست آمد.
Ali Nejad, D., and H. Goli. 2005. Nanocomposites and their applications. Zaban-e Tasvir Publications. 120 pp. (In Persian)
Amin, F., and M.O. Mohammad. 2015. Effect of nano-zinc chelate and nano-biofertilizer on yield and yield components of maize (Zea mays ), under water stress condition. Indian Journalof Natural Sciences. 5(29): 4614-4620.
Atlassi Pak, V., and O. Bahmani. 2017. Evaluation of ion distribution in different tissueso of wheat (Triticum aestivum) cultivars differing in salt tolerance. Journal of Crop Production and Processing. 7(1): 1-16. (In Persian).
Bedoussac, L., E.P. Journet, H. Hauggaard Nielsen, C. Naudin, G. Corre Hellou, E.S. Jensen, L. Prieur, and Justes, E. 2015. Ecological principles underlying the increase of productivity achieved by cereal grain legume intercrops in organic farming. A review. Agronomy for Sustainable Development. 35(3): 911-935.
Dapkekar, A., P. Deshpande, M.D. Oak, K.M. Paknikar, and J.M. Rajwade. 2018. Zinc use efficiency is enhanced in wheat through nanofertilization. Scientific Reports. 8(1): 6832.
Dehghan Harati, R., A. Morovati, and D. AbadikhahDeh Ali. 2013. An investigation on yield and yield components of maize ear (SC704 variety) under the effects of time and different levels of foliar application of zinc chelate in Khatam city. Plant and Ecosystem. 9(1): 17-28. (In Persian).
Dhima, K.V., A.A. Lithourgidis, I.B. Vasilakoglou, and C.A. Dordas. 2007. Competition indices of common vetch and cereal intercrops in two seeding ratios. Field Crops Research. 100: 249-256.
Emami, A. 1996. Plant decomposition methods. Vol. 1. Technical leaflet No. 982. Soil and Water. Research Institute, Tehran, Iran. (In Persian).
Farina, F., and M.M. Omidi. 2015. Effect of nano-zinc chelate and nano-biofertilizer on yield and yield components of maize (Zea mays ), under water stress condition. Indian Journal of Natural Sciences. 5(29): 4614-4624.
Fathi, Gh. 2005. Effects of planting pattern and density on optical attenuation coefficient, radiation absorption, and grain yield of sweet maize (hybrid SC402). Agricultural Sciences and Natural Resources. 12: 131-143. (In Persian)
Ghaffari Malayeri, M., G.H. Akbari, and A. Mohammadzadeh. 2012. Yield and yield components of maize to soil application and foliar application of micronutrients. Iranian Crop Research. 10(2): 368-373. (In Persian).
Gomaa, M.A., E.E. Kandil, and A.M.M. Ibrahim. 2020. Response of maize to organic fertilization and some nano-micronutrients. Egyptian Academic Journal of Biological Sciences. 11(1): 13-21.
Jam,, A. Ebadie, and G. Parmoon. 2016. The role of Iron and zinc on tuber yield and yield components of potato. Journal of crop Ecophysiology. 9(2):177-190. (In Persian).
Jamshidi, K.H., D. Mazaheri, N. Majnoon Hosseini, H. Rahimian, and S.A. Payghambari. 2008. Yield evaluation in intercropping of maize (Zea mays) and cowpea (Vignaanguiculata). Agriculture and Horticulture. 80: 109-118. (In Persian).
Katebi, R., J. KhaliliMahalleh, K. Kharazmi, R. Valilou, and A. Pirzad 2016. The effect of planting density on some agronomic traits of maize in intercropping with cowpea. Journal of Agricultural Science and Sustainable Production. 26(1): 1-18. (In Persian).
Li, Q.S., L.K. Wu, J. Chen, M.A. Khan, X.M. Luo, and W.X. Lin. 2016. Biochemical and microbial properties of rhizospheres under maize/peanut intercropping. Journal of Integrative Agriculture. 15: 101-110.
Liu, D.Y., W. Zhang, Y.M. Liu, X.P. Chen, and C.Q. Zou. 2020. Soil application of zinc fertilizer increases maize yield by enhancing the kernel number and kernel weight of inferior grains. Frontiers in Plant Science. 11: 188- 198.
Mahil, E.I.T., and B.N.A. Kumar. 2019. Foliar application of nanofertilizers in agricultural crops.A review. Journal of Farm Science. 32(3): 239-249.
Mazaherinia, S., A.R. Astaraei, A. Fotovat, and A. Monshi. 2010. Nano-iron-oxide particles efficiency on Fe, Mn, Zn and Cu concentrations in wheat plant. World Applied Sciences. 7: 36-40.
Mikic, A., B. Cupinax, D. Rubiales, V. Mihailovi, L. Sarunaitek, J. Fustec, S. Antanasovicx, D. Krsticx, L. Bedoussac, L. Zoricx, V. Dor Cevic, V. Peric, and M. Srebri. 2014. Models, developments, and perspectives of mutual legume intercropping. Advances in Agronomy. 130: 1-83.
Nasrollahzadeh Asl, A., A. Chavooshgholi, A. Valizadegan, R. Valilou, and V. Nasrallahzadeh Asl. 2012. Evaluation of sunflower and pinto bean intercropping by the additive method. Journal of Agricultural Science and Sustainable Production. 22(2): 79-90. (In Persian)
Nassary, E.K., F. Baijukya, and P.A. Ndakidemi. 2020. Assessing the productivity of common bean in intercrop with maize across agro-ecological zones of smallholder farms in the northern highlands of Tanzania. Agriculture. 10(117): 2-15.
Nazari, S.H., A. Zand, S. Asadi, and F. Golzardi. 2012. The effect of incremental intercropping and maize and mung cowpea replacement on yield, yield components and weed biomass. 4(2): 97-110. (In Persian).
Nouraein, M. 2019. Effect of nanofertilizers and biofertilizers on yield of maize: biplot analysis. 25(2): 121–130.
Papakosta, D.K., and A.A. Gagianas. 1991. Nitrogen and dry matter accumulation, remobilization, and losses for Mediterranean wheat during grain filling. Agronomy Journal. 83(5): 864-870.
Pelzer, E., M. Bazot, D. Makowski, G. Corre-Hellou, C. Naudin, and M. Al-Rifai. 2012. Pea-wheat intercrops in low-input conditions combine high economic performances and lowenvironmental impacts. European Journal of Agronomy. 40: 39–53.
Pirzad, A., and F. Shokrani. 2012. Effects of iron application on growth characters and flower yield of Calendula officinalis under water stress. World Applied Sciences Journal. 18(9): 1203-1208.
Ravi, S., H.T. Channal, N.S. Hebsur, B.N. Patil, and P.R. Dharmatti. 2008. Effect ofsulphur, zinc and iron nutrition on growth, yield, nutrient uptake and quality ofsafflower (Carthamus tinctorius). Karnataka Journal Agriculture Science. 32: 382-385.
Rostami, L., M. Mandani, S. Khorramdel, A. Koochaki, and M. Nasiri Mahallati. 2009. Effects of different densities of maize and cowpea intercropping on crop yield and weed population. Journal of Weed Research. 1(2): 37-51. (In Persian).
Sabeki, M., M.R. Asgharipour, A. Ghanbari, and K. Miri. 2018. The effect of nano-iron chelated fertilizer on agronomic aspects of millet- cowpea intercropping. Journal of Animal & Plant Sciences. 28(5): 1501-1507.
Saha, S., B. Mandal, G.C. Hazra, A. Dey, M. Chakraborty, B. Adhikari, S.K. Mukhopadhyay, and R. Sadhukhan. 2015. Can agronomic biofortification of zinc be benign for iron in cereals? Journal of Cereal Science. 65: 186-191.
SheshBahreh, J., and M. Movahedi-Dehnavi. 2012. The effect of zinc and iron foliar application on soybean seed vigor grown under drought stress conditions. Electronic Journal of Crop Production. 35: 5-19. (In Persian).
Shojaei, H., and H. Mokarian. 2014. The effect of nano and non-nano zinc oxide foliar application on yield and yield components of mung cowpea, Vigna radiata , under drought stress conditions. Iranian Journal of Crop Research. 4(12): 727-737.
Thomas, J., A. Mandal, R. Raj Kumar, and A. Chordia. 2009. Role of biologically active amino acid formulations on quality and crop productivity of tea (Camellia sp.). International Journal of Agricultural Research. 4: 228-236.
Tignegre, B.S., A. Labri, A. Tenkouano, A. Nurudeen, M. Asante, R. Boateng, A. Rouamba, M.C. Sobgui, and T. Chagomoka. 2018. Optimization of maize-vegetable (African eggplant and pepper) intercrops in northern, upper west and upper east regions of Ghana. JOJ Horticulture and Arboriculture. 1(2): 29-33.
Tittonell, P., S. Zingore, M.T. Van Wijk, M. Corbeels, and K.E. Giller. 2007. Nutrient use efficiencies and crop responses to N, P and manure applications in Zimbabwean soils: exploring management strategies across soil fertility gradients. Field Crops Research. 100: 348-368.
Yaghoobi,R. ,A. Roozbahani, and M.R. Akhavan Mohseni. 2019. Evaluating of role of soluble potassium sulfate and chelated iron on corn yield and yield components under water deficit stress. Journal of Crop Ecophysiology. 12(4): 599 – 614. (In Persian).
Yousef pour, A. ,and E. Farajzadeh Memari Tabrizi. 2018. Evaluation of micronutrient application at different growth stages on yield and yield components grain quality of sweet corn. Journal of Crop Ecophysiology. 12(2): 287-302 .(In Persian).
Yu, H., P. Berentsen, N. Heerink, M. Shi, and W. Vanderwer. 2019. Thefuture of intercropping under growing resource scarcity and declining grainprices-A model analysis based on acase study in North west China. Agricultural Systems. 176: 1-13.
Ziaian, A., and M.J. Malakooti. 2003. A greenhouse study on the effects of iron, manganese, zinc, and copper consumption on wheat production in highly calcareous soils of Fars province. Balanced nutrition of wheat. Proceedings, M.J. Kingdom. Agricultural Training Publications, Tehran, Iran. (In Persian).
_||_Ali Nejad, D., and H. Goli. 2005. Nanocomposites and their applications. Zaban-e Tasvir Publications. 120 pp. (In Persian)
Amin, F., and M.O. Mohammad. 2015. Effect of nano-zinc chelate and nano-biofertilizer on yield and yield components of maize (Zea mays ), under water stress condition. Indian Journalof Natural Sciences. 5(29): 4614-4620.
Atlassi Pak, V., and O. Bahmani. 2017. Evaluation of ion distribution in different tissueso of wheat (Triticum aestivum) cultivars differing in salt tolerance. Journal of Crop Production and Processing. 7(1): 1-16. (In Persian).
Bedoussac, L., E.P. Journet, H. Hauggaard Nielsen, C. Naudin, G. Corre Hellou, E.S. Jensen, L. Prieur, and Justes, E. 2015. Ecological principles underlying the increase of productivity achieved by cereal grain legume intercrops in organic farming. A review. Agronomy for Sustainable Development. 35(3): 911-935.
Dapkekar, A., P. Deshpande, M.D. Oak, K.M. Paknikar, and J.M. Rajwade. 2018. Zinc use efficiency is enhanced in wheat through nanofertilization. Scientific Reports. 8(1): 6832.
Dehghan Harati, R., A. Morovati, and D. AbadikhahDeh Ali. 2013. An investigation on yield and yield components of maize ear (SC704 variety) under the effects of time and different levels of foliar application of zinc chelate in Khatam city. Plant and Ecosystem. 9(1): 17-28. (In Persian).
Dhima, K.V., A.A. Lithourgidis, I.B. Vasilakoglou, and C.A. Dordas. 2007. Competition indices of common vetch and cereal intercrops in two seeding ratios. Field Crops Research. 100: 249-256.
Emami, A. 1996. Plant decomposition methods. Vol. 1. Technical leaflet No. 982. Soil and Water. Research Institute, Tehran, Iran. (In Persian).
Farina, F., and M.M. Omidi. 2015. Effect of nano-zinc chelate and nano-biofertilizer on yield and yield components of maize (Zea mays ), under water stress condition. Indian Journal of Natural Sciences. 5(29): 4614-4624.
Fathi, Gh. 2005. Effects of planting pattern and density on optical attenuation coefficient, radiation absorption, and grain yield of sweet maize (hybrid SC402). Agricultural Sciences and Natural Resources. 12: 131-143. (In Persian)
Ghaffari Malayeri, M., G.H. Akbari, and A. Mohammadzadeh. 2012. Yield and yield components of maize to soil application and foliar application of micronutrients. Iranian Crop Research. 10(2): 368-373. (In Persian).
Gomaa, M.A., E.E. Kandil, and A.M.M. Ibrahim. 2020. Response of maize to organic fertilization and some nano-micronutrients. Egyptian Academic Journal of Biological Sciences. 11(1): 13-21.
Jam,, A. Ebadie, and G. Parmoon. 2016. The role of Iron and zinc on tuber yield and yield components of potato. Journal of crop Ecophysiology. 9(2):177-190. (In Persian).
Jamshidi, K.H., D. Mazaheri, N. Majnoon Hosseini, H. Rahimian, and S.A. Payghambari. 2008. Yield evaluation in intercropping of maize (Zea mays) and cowpea (Vignaanguiculata). Agriculture and Horticulture. 80: 109-118. (In Persian).
Katebi, R., J. KhaliliMahalleh, K. Kharazmi, R. Valilou, and A. Pirzad 2016. The effect of planting density on some agronomic traits of maize in intercropping with cowpea. Journal of Agricultural Science and Sustainable Production. 26(1): 1-18. (In Persian).
Li, Q.S., L.K. Wu, J. Chen, M.A. Khan, X.M. Luo, and W.X. Lin. 2016. Biochemical and microbial properties of rhizospheres under maize/peanut intercropping. Journal of Integrative Agriculture. 15: 101-110.
Liu, D.Y., W. Zhang, Y.M. Liu, X.P. Chen, and C.Q. Zou. 2020. Soil application of zinc fertilizer increases maize yield by enhancing the kernel number and kernel weight of inferior grains. Frontiers in Plant Science. 11: 188- 198.
Mahil, E.I.T., and B.N.A. Kumar. 2019. Foliar application of nanofertilizers in agricultural crops.A review. Journal of Farm Science. 32(3): 239-249.
Mazaherinia, S., A.R. Astaraei, A. Fotovat, and A. Monshi. 2010. Nano-iron-oxide particles efficiency on Fe, Mn, Zn and Cu concentrations in wheat plant. World Applied Sciences. 7: 36-40.
Mikic, A., B. Cupinax, D. Rubiales, V. Mihailovi, L. Sarunaitek, J. Fustec, S. Antanasovicx, D. Krsticx, L. Bedoussac, L. Zoricx, V. Dor Cevic, V. Peric, and M. Srebri. 2014. Models, developments, and perspectives of mutual legume intercropping. Advances in Agronomy. 130: 1-83.
Nasrollahzadeh Asl, A., A. Chavooshgholi, A. Valizadegan, R. Valilou, and V. Nasrallahzadeh Asl. 2012. Evaluation of sunflower and pinto bean intercropping by the additive method. Journal of Agricultural Science and Sustainable Production. 22(2): 79-90. (In Persian)
Nassary, E.K., F. Baijukya, and P.A. Ndakidemi. 2020. Assessing the productivity of common bean in intercrop with maize across agro-ecological zones of smallholder farms in the northern highlands of Tanzania. Agriculture. 10(117): 2-15.
Nazari, S.H., A. Zand, S. Asadi, and F. Golzardi. 2012. The effect of incremental intercropping and maize and mung cowpea replacement on yield, yield components and weed biomass. 4(2): 97-110. (In Persian).
Nouraein, M. 2019. Effect of nanofertilizers and biofertilizers on yield of maize: biplot analysis. 25(2): 121–130.
Papakosta, D.K., and A.A. Gagianas. 1991. Nitrogen and dry matter accumulation, remobilization, and losses for Mediterranean wheat during grain filling. Agronomy Journal. 83(5): 864-870.
Pelzer, E., M. Bazot, D. Makowski, G. Corre-Hellou, C. Naudin, and M. Al-Rifai. 2012. Pea-wheat intercrops in low-input conditions combine high economic performances and lowenvironmental impacts. European Journal of Agronomy. 40: 39–53.
Pirzad, A., and F. Shokrani. 2012. Effects of iron application on growth characters and flower yield of Calendula officinalis under water stress. World Applied Sciences Journal. 18(9): 1203-1208.
Ravi, S., H.T. Channal, N.S. Hebsur, B.N. Patil, and P.R. Dharmatti. 2008. Effect ofsulphur, zinc and iron nutrition on growth, yield, nutrient uptake and quality ofsafflower (Carthamus tinctorius). Karnataka Journal Agriculture Science. 32: 382-385.
Rostami, L., M. Mandani, S. Khorramdel, A. Koochaki, and M. Nasiri Mahallati. 2009. Effects of different densities of maize and cowpea intercropping on crop yield and weed population. Journal of Weed Research. 1(2): 37-51. (In Persian).
Sabeki, M., M.R. Asgharipour, A. Ghanbari, and K. Miri. 2018. The effect of nano-iron chelated fertilizer on agronomic aspects of millet- cowpea intercropping. Journal of Animal & Plant Sciences. 28(5): 1501-1507.
Saha, S., B. Mandal, G.C. Hazra, A. Dey, M. Chakraborty, B. Adhikari, S.K. Mukhopadhyay, and R. Sadhukhan. 2015. Can agronomic biofortification of zinc be benign for iron in cereals? Journal of Cereal Science. 65: 186-191.
SheshBahreh, J., and M. Movahedi-Dehnavi. 2012. The effect of zinc and iron foliar application on soybean seed vigor grown under drought stress conditions. Electronic Journal of Crop Production. 35: 5-19. (In Persian).
Shojaei, H., and H. Mokarian. 2014. The effect of nano and non-nano zinc oxide foliar application on yield and yield components of mung cowpea, Vigna radiata , under drought stress conditions. Iranian Journal of Crop Research. 4(12): 727-737.
Thomas, J., A. Mandal, R. Raj Kumar, and A. Chordia. 2009. Role of biologically active amino acid formulations on quality and crop productivity of tea (Camellia sp.). International Journal of Agricultural Research. 4: 228-236.
Tignegre, B.S., A. Labri, A. Tenkouano, A. Nurudeen, M. Asante, R. Boateng, A. Rouamba, M.C. Sobgui, and T. Chagomoka. 2018. Optimization of maize-vegetable (African eggplant and pepper) intercrops in northern, upper west and upper east regions of Ghana. JOJ Horticulture and Arboriculture. 1(2): 29-33.
Tittonell, P., S. Zingore, M.T. Van Wijk, M. Corbeels, and K.E. Giller. 2007. Nutrient use efficiencies and crop responses to N, P and manure applications in Zimbabwean soils: exploring management strategies across soil fertility gradients. Field Crops Research. 100: 348-368.
Yaghoobi,R. ,A. Roozbahani, and M.R. Akhavan Mohseni. 2019. Evaluating of role of soluble potassium sulfate and chelated iron on corn yield and yield components under water deficit stress. Journal of Crop Ecophysiology. 12(4): 599 – 614. (In Persian).
Yousef pour, A. ,and E. Farajzadeh Memari Tabrizi. 2018. Evaluation of micronutrient application at different growth stages on yield and yield components grain quality of sweet corn. Journal of Crop Ecophysiology. 12(2): 287-302 .(In Persian).
Yu, H., P. Berentsen, N. Heerink, M. Shi, and W. Vanderwer. 2019. Thefuture of intercropping under growing resource scarcity and declining grainprices-A model analysis based on acase study in North west China. Agricultural Systems. 176: 1-13.
Ziaian, A., and M.J. Malakooti. 2003. A greenhouse study on the effects of iron, manganese, zinc, and copper consumption on wheat production in highly calcareous soils of Fars province. Balanced nutrition of wheat. Proceedings, M.J. Kingdom. Agricultural Training Publications, Tehran, Iran. (In Persian).