Nitrogen fertilizer and faba bean density as sources of nitrogen supply in sustainable production of forage corn

Document Type : Original Article

Authors

1 Department of Agronomy and Plant Breeding, Faculty of Agriculture and Natural Resources, University of Mohaghegh Ardabili, Ardabil, Iran

2 Department of Plant and Soil Sciences, Crop Physiology, University of Massachusetts, Amherst. USA.

Abstract

Introduction
Some studies have reported that application of chemical fertilizers, especially nitrogen, is one of the most appropriate methods to increase crop production and maintain food security in the world. However, it should also be noted that the improper use of nitrogen fertilizers can disrupt natural ecosystems. Alternative methods can be used to prevent this, such as the use of plants with biological nitrogen fixation (e.g., legumes). Faba bean is one of the most important varieties of this family (Fabaceae) and contains 24-30% protein and 51-68% carbohydrates. This plant is one of the most important spices of the genus (Vicia) and has a high yield compared to other legumes. Due to its environmental, economic and agroecological performance, faba bean can improve the sustainability of agricultural ecosystems. Corn (Zea mays L.) is one of the most important annual cereals. However, maize cultivation is not economical because it requires nitrogen fertilizer, and improper use of nitrogen also increases ecosystem instability. Incorporating legumes into cropping systems is critical for sustainable management of agricultural systems and reducing nitrogen fertilizer requirements for corn production.
 
Materials and Methods
A two-year experiment was conducted in 2018-2019 as a factorial experiment based on a randomized complete block design with three replications at the research farm of the Faculty of Agriculture and Natural Resources, university of Mohaghegh Ardabili, Ardabil, Iran. The experimental treatments were different plant densities of faba bean (25, 35, 40 and 80 plants m-2) and different nitrogen fertilizer rates (0, 100, 200 and 300 kg ha-1) of forage corn. In this experiment, the faba bean variety Shadan was planted and manually harvested at the physiological maturity stage. The corn variety was a single cross hybrid 201, which was planted at a density of 80000 plants ha-1 in the rows with faba bean residues. At the V5 stage of corn, N fertilizer (as urea) was applied in 3 stages. Three corn plants were harvested at the milk stage and then oven dried at 70°C for 72 h and weighed. Traits studied in this experiment included chlorophyll index, plant height, root nodule dry weight, root dry weight, number of root nodules, and grain yield in faba bean, and chlorophyll index, protein harvest index, plant height, number of leaves per plant, physiological nitrogen efficiency, nitrogen uptake efficiency, and dry matter yield in forage corn. Statistical analysis of data was performed using SAS 9.4 software, and significant differences between treatment means were tested using the Duncan's Multiple Range Test at P< 0.05.
 
Results and Discussion
Faba bean
The highest grain yield (g m-2), plant height (cm) and chlorophyll index of faba bean were obtained at the density of 80 plant m-2. At the densities of 25 and 35 plants m-2, the number of root nodules and the dry weight of root nodules (g) were the highest. As plant density increased, root dry weight (g m-2) also increased, so that the density of 80 plants m-2 had the highest root dry weight per m2. The highest fertility rate was observed at the densities of 80 and 40 plants m-2.
Corn
Our results showed that the interaction between faba bean density and N fertilizer had effects on plant height, chlorophyll index, protein harvest index, physiological nitrogen efficiency, nitrogen uptake efficiency, and dry forage yield. The results of the mean comparisons showed that the highest dry forage yield was obtained at the density of 40 faba bean plants+200 kg N ha-1 an increase of 155% over the control treatment. The highest number of leaves was observed in the treatments at the density of 40 faba bean plants+100 kg N ha-1, at the density of 40 faba bean plants+200 kg N ha-1 and at the density of 35 faba bean plants+200 kg N ha-1. The density of 40 plant of faba bean+100 kg N ha-1 and the density of 40 plant of faba bean+200 kg N ha-1 had the highest plant height. The highest chlorophyll index was obtained at the the density of 40 faba bean plants+200 kg N ha-1. Finally, the results showed that employment of faba bean in rotation and non-application of nitrogen fertilizer increased nitrogen uptake efficiency of forage corn.
 
Conclusion
Comparison of the different treatments showed that the density of 40 plants of faba bean and 200 kg N ha-1 was superior in most of the evaluated traits. Overall, the results suggest that the use of faba bean in crop rotation is an appropriate approach to reduce the use of chemical fertilizers in agricultural systems, according to the results, the use of the density of 40 plants of faba bean and 200 kg N ha-1 were recommended under the same weather conditions.

Keywords

Main Subjects


  1. Abbasi, M.K., Khaliq, A., Shafiq, M., Kazmi, M., and Imran, A. 2010. Comparatative effectiveness of urea N, poultry manure and their combination in changing soil properties and maize productivity under rainfed conditions in northeast Pakistan. Experimental Agriculture 46: 211-230.
  2. Afzal, M., Ahmad, A., and Ahmad, A.U. H. 2012. Effect of nitrogen on growth and yield of sorghum forage under three cutting system. Cercetari Agronomice in Moldova 4(152): 57-64.
  3. Afzalinia, S., and Zabihi, J. 2014. Soil compaction variation during corn growing season under conservation tillage. Soil and Tillage Research 137: 1-6.
  4. Al-Suhaibani, N., El-Hendawy, S., and Schmidhalter, U. 2013. Influence of varied plant density on growth, yield and economic return of drip irrigated Faba bean (Vicia faba). Turkish Journal of Field Crops 18(2): 185-197.
  5. Ansarinia, E. 2010. Effect of irrigation and nitrogen levels on yield and agronomical traits of sunflower. MSc. Thesis in Agriculture. Department of Agriculture, Azad University of Birjand, Iran. (in Persian).
  6. Aulakh, M.S., Manchanda, J.S., Garg, A.K., Kumar, S., Dercon, G., and Nguyen, M. 2012. Crop production and nutrient use efficiency of conservation agriculture for soybean-wheat rotation in the Indo-Gangetic Plains of Northwestern India. Soil & Tillage Research 120: 50-
  7. Berkenkamp, B., and Meeres, J. 1986. Faba bean as forage in the parklands of Alberta. Canadian Journal of Plant Science 66: 167-169.
  8. Beslemes, D.F., Tigka, E.L., Efthimiadis, P., and Danalatos, N.G. 2013. Maize biomass production, N-use efficiency and potential bioethanol yield, under different cover cropping managements, nitrogen Influxes and soil types, in Mediterranean climate. Journal of Agriculture Science 5(7): 189-205.
  9. Chen, Y., and Barak, Ph. 1982. Iron nutrition of plants in Calcareous s Advances in Agronomy 35: 217-240.
  10. Chen, Z.M., Wang, Q., Wang, H.Y., Bao, L., and Zhou, J.M. 2018. Crop yields and soil organic carbon fractions as influenced by straw incorporation in a rice-wheat cropping system in southeastern China. Nutrient Cycling in Agroecosystems 112: 61-
  11. Demari, G.H., Ca, I.R., Monteiro, C.J.B., and T Pedó, T. 2016. Importance of NITR. Journal of Current Research 8(08): 36629-36634.
  12. Dolatmand Shahri, N., and Tahmasebi, I. 2017. Effect of nitrogen and plant density on photosynthetic capacity, yield components and seed yield of Corn cultivar ‘Mv500’ in summer p Journal of Crop Production and Processing 7(1): 87-99.
  13. El-Gizawy, N.Kh.B. 2009. Effects of nitrogen rates and plant density on agronomic nitrogen use efficiency and maize yield following wheat and Faba bean. American-Eurasian Journal of Agriculture and Environ Science 5(3): 378-386.
  14. Entz, M.H., Baron, V.S., Carr, P.M., Meyer, D.W., Smith, S.R., and McCaughey, W.P. 2002. Potential of forages to diversify cropping systems in the Northern Great Plains. Agronomy Journal 94: 240-
  15. Etemadi, F., Hashemi, M., Zandvakili, O., and Sadeghpour, A. 2018. Nitrogen contribution from winter-killed faba bean cover crop to spring-sown sweet corn in conventional and no-till s Agronomy Journal 110(2): 455-462.
  16. Gan, Y.T., Miller, P.R., Mc Conkey, B.G., Zentner, R.P., Liu, P.H., and McDonald, C.L. 2003. Optimum plant population density for chickpea and dry pea in a semiarid environment. Canadian Journal of Plant Science 83: 1-
  17. Gezahegn, M.A. 2019. Review on effect of plant density and planting arrangement on faba bean production. World Journal of Agricultural Sciences 15(4): 261-268.
  18. Ghazvineh, S., and Yousefi, M. 2012. Study the Effect of micronutrient application on yield and yield components of Maize. American-Eurasian Journal of Agricultural & Environmental Sciences 12(2): 144-
  19. Guler, S., Hayriye Ibrikci, H., and Buyuk, G. 2006. Effects of different nitrogen rates on yield and leaf nutrient contents of drip-fertigated and greenhouse-grown cucumber. Asian Journal of Plant Science 5(4): 657-662.
  20. Hamzei, J., Seyedi, M., and Babaei, M. 2015. Effect of density and nitrogen on seed quantity and quality of winter rapeseed in Hamedan conditions. Crop Production 8(1): 143-159. (in Persian).
  21. Harries, E., Carmona, L., Muñoz, A., Ibeas, J.I., Read, N.D., Gandía, M., and Marcos, J.F. 2013. Genes involved in protein glycosylation determine the activity and cell internalization of the antifungal peptide PAF26 in Saccharomyces cerevisiae. Fungal Genetics and Biology 58: 105-115.
  22. Hasanalideh, A.H., and Hojati, M. 2012. Enhancing yield and nitrogen use efficiency of Brassica Napus using an integrated fertilizer management. Advances in Environmental Biology 6(2): 641-647.
  23. Hatfield, J.L., and Prueger, J.H. 2004. Nitrogen over-use, under-use, and efficiency. Crop Science 26: 156-168.
  24. Huggins, D.R., and Pan, W.L. 1993. Nitrogen efficiency component analysis: an evaluation of cropping system differences in productivity. Agronomy Journal 85: 898-905.
  25. Iqbal, M.S., Hafeez, M.N., Wattoo, J.I., Ali, A., Sharif, M.N., and Rashid, B. 2016. Prediction of host-derived miRNAs with the potential to target PVY in potato plants. Front Genetics 7:
  26. Issaka, F., Zhang, Z., Zhao, Z.Q., Asenso, E., Li, J.H., and Li, Y.T. 2019. Sustainable conservation tillage improves soil nutrients and reduces nitrogen and phosphorous losses in maize farmland in Southern China. Sustainability 11: 2397.
  27. Jensen, E.S., Peoples, M.B., and Hauggaard-Nielsen, H. 2010. Faba bean in cropping systems. Field Crop Research 115: 203-
  28. Kebede, M., Sharma, J.J., Tana, T., and Nigatu, L. 2015. Effect of plant spacing and weeding frequency on weed infestation, yield components, and yield of common bean (Phaseolus vulgaris) in Eastern Ethiopia. East African Journal of Sciences 9: 1-14.
  29. Khalghani, J., and Koocheki, A. 1996. Understanding the Basics of Crop Production (Ecophysiological Approach). Ferdowsi University of Mashhad Press. 369 p.
  30. Khalil, S.K., Wahab, A., Rehman, A., Muhammad, F., Wahab, S., Khan, A.Z., Zubair, M., Shah, M.K., Khalil, I.H., and Amin, R. 2010. Density and planting date influence phenological development assimilate partitioning and dry matter production of faba bean. Pakistan Journal of Botany 42(6): 3831-3838.
  31. Lamptey, S., Li, L., and Yeboah, S. 2018. Reduced tillage practices without crop retention improved soil aggregate stability and maize (Zea mays) yield. Ghana Journal of Horticulture 13(1): 50-69.
  32. Lamptey, S., Yeboah, S., and Li, L. 2018. Response of maize forage yield and quality to nitrogen fertilization and harvest time in semi-arid Northwest China. Asian Journal of Research in Agriculture and Forestry 1: 1-10.
  33. Liu, G.Z., Hou, P., Xie, R.Z., Ming, B., Wang, K.R., Xu, W.J., Liu, W.M., Yang, Y.S., and Li, S.K. 2017. Canopy characteristics of high-yield maize with yield potential of 22.5 Mg ha −1. Field Crops Research 213: 221-
  34. Liu, S., Xing, , Westervelt, D.M., Liu, S., Ding, D., Fiore, A.M., Kinney, P.L., Zhang, Y., He, M.Z., Zhang, H., Sahu, S.K., Zhang, F., Zhao, B., and Wang, S. 2021. Role of emission controls in reducing the 2050 climate change penalty for PM2.5in China. Science Total Environment 765: 144338.
  35. Lopez-Bellido, L., Lopez-Bellido, R.J., Castillo, J.E., and Lopez-Bellido, F.J. 2001. Effects of long-term tillage, crop rotation and nitrogen fertilization on bread-making quality of hard red spring wheat. Field Crops Research 72: 197-
  36. Maadi, B., Fathi, G., Siadat, S.A., Alami Saeid, K., and Jafari. S. 2012. Effects of preceding crops and nitrogen rates on grain yield and yield components of wheat (Triticum aestivum). World Applied Sciences Journal 17(10): 1331-1336.
  37. Mohamed, S.S.E., and Babiker, H.M. 2012. Effects of Rhizobium inoculation andurea fertilization on faba bean (Vicia faba) production in a semi-desert zone. Advances in Environmental Biology 6: 824-830.
  38. Naderi, F., Siadat, S.A., and Rafiee, M. 2010. Effect of planting date and plant density on grain yield and yield components of two maize hybrids as second crop in Khorram Abad. Iranian Journal of Crop Sciences 12: 31-41. (in Persian with English abstract).
  39. Ojiem, J.O., Franke, A.C., Vanlauwe, B., de Ridder, N., and Giller, K.E. 2014. Benefits of legume-maize rotations: assessing the impact of diversity on the productivity of smallholders in Western Kenya. Field Crop Research 168: 75-
  40. Olojugba, M.R., and Ibiloye, J.O. 2019. Inter and active effect of tillage and nitrogen fertilizer on Maize (Zea mays) performance on a humid Alfisol Southwestern, Nigeria. Asian Journal Soil Science and Plant Nutrition 1-11.
  41. Perry, L.J., and Compton, W.A. 1977. Serial measures of dry matter accumulation and forage quality of leaves, stalks and ear of three maize hybrids. Agronomy Journal 69: 751-
  42. Prusiński, J. 2022. Effect of row spacing and plant density on the yield of Faba bean under very differentiated humidity c Journal of Agricultural Science 14(1): 1-10.
  43. Sangoi, L., Ernani, P.R., and Da Silva, P.R.F. 2007. Maize response to nitrogen fertilization timing in two tillage systems in a soil with high organic matter content. Revista Brasileira de Ciência do Solo 31: 507-
  44. Seyedi, M., Hamzei, J., Ahmadvand, G., and Abutalebian, M.A. 2012. The evaluation of weed suppression and crop production in barley-chickpea intercrops. Sustainable Agricultural and Production Science 22(3): 101-114. (in Persian with English abstract).
  45. Shoaei, Sh., Rafiei, F., and Kashani, A. 2009. Effect of crop rotation and nitrogen fertilizer on N, P, K concentration and wheat yield. New Agricultural Science 5(17): 27-36. (in Persian with English abstract).
  46. Siczek, A., and Lipiec, J. 2016. Impact of Faba bean-seed Rhizobial inoculation on microbial activity in the rhizosphere soil during growing s International Journal of Molecular Sciences 17: 784.
  47. Singh, A.K., Bhatt, B.P., Sundaram, P.K., Gupta, A.K., and Singh, D. 2013. Planting geometry to optimize growth and productivity in faba bean (Vicia faba) and soil fertility. Journal of Environmental Biology 34(1): 117.
  48. Tadayyon, M.R., and Ghorbaninejad, A.J. 2012. Effect of supplementary irrigation and compost application on morphological triats and yield of two chickpea (Cicer arietinum) cultivars. Iranian Journal of Pulses Research 3(2): 31-44. (in Persian with Enlish abstract).
  49. Tariq Jan, M., Jamal Khan, M., Khani, A., Arifi, M., Shafi, M., and Farmanullah, H. 2010. Wheat nitrogen indices response to nitrogen source and application time. Pakistan Journal of Botany 42 (6): 4267-4279.
  50. Tolera, A., Daba, F., and Friesen, D.K. 2009. Effects of crop rotation and N-P fertilizer rate on grain yield and related characteristics of Maize and soil fertility at Bako Western Oromia, Ethiopia. East African Journal of Science 3: 70-79.
  51. Uzoh, I.M., Arizechukwu Igwe, Ch., Okebalama, C.B., and Babalola, O.O. 2019. Legume-maize rotation effect on maize productivity and soil fertility parameters under selected agronomic practices in a sandy loam soil. Scientific Reports 9: 8539.
  52. Vesterager, J.M., Nielsen, N.E., and Hogh-Jensen, H. 2007. Nitrogen budgets in a crop sequences with or without phosphorus fertilized cowpea in the maize based cropping 104 system of semi-arid eastern Africa. African Journal of Agricultural Research 2(6): 261-268.
  53. Wasaya, A., Tahir, M., Yasir, T.A., Akram, M., Farooq, O., and Sarwar, N. 2018. Soil physical properties, nitrogen uptake and grain quality of maize (Zea mays) as affected by tillage systems and nitrogen application. Italian Journal of Agronomy 13(4): 324-331.
  54. Xiao, K., Xu, J., Tang, C., Zhang, J., and Brookes, P.C. 2013. Differences in carbon and nitrogen mineralization in soils of differing initial pH induced by electro kinesis and receiving crop residue amendments. Soil Biology & Biochemistry 67: 70-84.
  55. Yoseftabar, S., Fallah, A., and Daneshian, J. 2012. Effect of split application of nitrogen fertilizer on spad valuse in hybrid rice. International Journal of Agriculture and Crop Sciences 4: 647-651.
CAPTCHA Image
Volume 13, Issue 2 - Serial Number 26
December 2022
Pages 121-138
  • Receive Date: 12 February 2022
  • Revise Date: 11 July 2022
  • Accept Date: 05 September 2022
  • First Publish Date: 22 December 2022