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Evaluation of intercropping of sweet corn and leguminous cover crops at various doses of nitrogen on production and land equivalence ratio

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Research Paper 03/11/2024
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Evaluation of intercropping of sweet corn and leguminous cover crops at various doses of nitrogen on production and land equivalence ratio

Jon Andri Efendi Tumanggor, D. W. Widjajanto, Baginda Iskandar Moeda Tampoebolon
Int. J. Agron. Agri. Res.25( 5), 1-11, November 2024.
Certificate: IJAAR 2024 [Generate Certificate]
Key: C. pubescensFresh forage yieldLand equivalence ratioP. phaseloidesSweet corn ear yield

Abstract

The study was aimed to determine and evaluate the effect of different levels of nitrogen fertilizer doses and planting patterns on chlorophyll content, sweet corn yield, leguminous cover crop (LCC) yield and land equivalent ratio (LER). A factorial randomized block design with 2 factors and 3 replications was used throughout the experiment. The first factor was the dose of nitrogen consisting of 4 doses, namely 0, 50, 100 and 150 kg nitrogen ha-1. The second factor was planting pattern, consisted of 3 planting pattern i.e. sole cropping sweet corn, intercropping sweet corn-Centrocema pubescens  and intercropping sweet corn- Pueraria phaseloides. In addition, monoculture planting of C. pubescens and P. phaseloides was also established to calculate LER. The results showed that increasing the dose of nitrogen had an impact on increasing the chlorophyll content and fresh cob yield of sweet corn. The fresh forage yield of P. phaseloides was significantly higher than that of C. pubescens. The LER value of sweet corn-LCC intercropping was more than 1, which means that intercropping was more profitable than sweet corn planted as a monoculture. Based on the results, it may be concluded that the highest sweet corn ear production can be achieved with application of 50-100 kg N ha-1 and to obtain highest LCC forage production may be done by intercropping sweet corn-P. phaseloides.

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Agung GAMS, Sardiana K, Nurjaya GMO. 2015. Effect of tropical legume cover crops on soil quality at dryland farming area in Bali, Indonesia. Int. J. Agron. Agric. Res. 6(3), 12-19.

Ahmed N, Habib U, Younis U, Irshad I, Danish S, Rahi AA, Munir TM. 2020. Growth, chlorophyll content and productivity responses of maize to magnesium sulphate application in calcareous soil. Open Agric. 5, 792-800. https://doi.org/10.1515/opag-2020-0023.

Almeida JCL de C, de Morais F, Araujo RP, Morenz MJ F, de Abreu JBR, Soares FA. 2019. Dry matter production and chemical composition of tropical forage legumes under different shading levels. Acta Scientiarum. Anim. Sci. 41, e43526.

Arnon DI. 1949. Copper enzymes in isolated chloroplasts polyphenoloxidase in Beta vulgaris. Plant Physiol. 24(1), 1-15.

Central Bureau of Statistics. 2021. Geography of Tembalang District, Semarang City, Central Java Province, Indonesia in figures 2021.

Central Bureau of Statistics. 2022. Indikator Tujuan Pembangunan Berkelanjutan dan Karakteristik Utama Sektor Pertanian 2021 (Hasil Survei Terintegrasi). BPS. Jakarta.

Chen P, Du Q, Liu X, Zhou L, Hussain S, Lei L, Song C, Wang X, Liu W, Yang F, Shu K, Liu J, Du J, Yang W, Yong T. 2017. Effects of reduced nitrogen inputs on crop yield and nitrogen use efficiency in a long-term maize-soybean relay strip intercropping system. PloS ONE 12(9), e0184503.

Clermont-Dauphin C, Suvannang N, Pongwichian P, Cheylan V, Hammecker C, Harmand J. 2016. Dinitrogen fixation by the legume cover crop Pueraria phaseloides and transfer of fixed N to Hevea brasiliensis on tree growth and vulnerability to drought. Agric. Ecosystems Environ. 217, 79-88.

De Bang TC, Husted S, Laursen KH, Persson DP, Schjoerring JK. 2020. The molecular-physiological functions of mineral macronutrients and their consequences for deficiency symptoms in plants. New Phytologist 229, 2446-2469.

Dhaliwal DS, Williams MM II. 2022. Evidence of sweet corn yield losses from rising temperatures. Scientific Reports 12, 18218.

Gao L, Li W, Ashraf U, Lu W, Li Y, Li C, Li G, Li G, Hu J. 2020. Nitrogen fertilizer management and maize straw return modulate yield and nitrogen balance in sweet maize. Agron. 10(3), 362.

Gunawan RR, Sulistyowati D, Ritonga AW, Krisnawato E, Adirianto B. 2022. Keragaan 23 varietas jagung manis (Zea mays saccharata Sturt) komersial. J. Agroekotek 14(2), 225-237.

Halim RA. 1997. Pueraria phaseloides (Roxb.) Benth. In Hanum, IF, van der Maesen, LJG (Eds.). Plant resources of South-East Asia No. 11 Auxiliary Plants. Backhuy Publishers, Leiden.

Hamzei J, Seyedi M. 2015. Evaluation of the effects of intercropping system on yield performance, land equivalent ratio and weed control. Agric. Res. 4(2), 202-207.

Khanal U, Stott KJ, Armstrong R, Nuttal JG, Herry F, Christy BP, Mitchell M, Riffkin PA, Wallace AJ, McCaskill M, Thayalakumaran T, O’Leary GJ. 2021. Intercropping-evaluating the advantages to broadacre systems. Agric. 11(5), 453.

Li C, Stomph T, Wakowski D, Li H, Zhang C, Zhang F, van der Werf W. 2023. The productive performance of intercropping. PNAS 120(2), e2201886120.

Lindstrom K, Mousavi SA. 2020. Effectiveness of nitrogen fixation in rhizobia. Microbial Biotechnol. 13(5), 1314-1335.

Liu X, Hu B, Chu C. 2022. Nitrogen assimilation in plants: current status and future prospects. J. Genetics Genomics 49, 394-404.

Lu Y, Song G, Wang Y, Wang L, Xu M, Zhou L, Wang L. 2023. Combining nitrogen effects and metabolomics to reveal the response mechanisms to nitrogen stress and the potential for nitrogen reduction in maize. J. Integrative Agric. 22(9), 2660-2672.

Maftukhah R, Keiblinger KM, Ngadisih N, Murtiningrum M, Kral RM, Mentler A, Hood-Nowotny R. 2023. Post-tin-mining agricultural soil regeneration using local organic amendments improves nitrogen fixation and uptake in a legume-cassava intercropping system. Land 12(5), 1107.

Maitra S, Hossain A, Brestic M, Skalicky M, Ondrisik P, Gitari H, Brahmachari K, Sankar T, Bhadra P, Palai JB, Jena J, Bhattacarya U, Duvvada SK, Lalichetti S, Sairam M. 2021. Intercropping—a low input agricultural strategy for food and environment security. Agron. 11(2), 343.

Mayberry D, Hau DK, Dida PR, Bria D, Praing J, Mata AD, Budisantoso E, Dalgliesh N, Quigley S, Bell L, Nulik J. 2021. Herbaceous legumes provide several options for increasing beef cattle productivity in Eastern Indonesia. Anim. Prod. Sci. 61, 698-707.

Mead R, Willey RW. 1980. The concept of a ‘land equivalent ratio’ and advantages in yields from intercropping. Expl. Agric. 16, 217-228.

Mu X, Chen Y. 2021. The physiological response of photosynthesis to nitrogen deficiency. Plant Physiol. Biochemist. 158, 76-82.

Muhammad I, Yang L, Ahmed S, Farooq S, Al-Ghamdi AA, Khan A, Zeeshan M, Elshikh MS, Abbasi AM, Zhou X. 2022. Nitrogen fertilizer modulates plant growth, chlorophyll pigments, and enzymatic activities under different irrigation regimes. Agron. 12(4), 845.

Nawar AI, Salama HSA, Khalil HE. 2020. Additive intercropping of sunflower and soybean to improve yield and land use efficiency: effect of thinning interval and nitrogen fertilization. Chilean J. Agric. Res. 80(2), 142-152.

Nunes-Nesi A, Fernie AR, Stitt M. 2010. Metabolic and signaling aspects underpinning the regulation of plant carbon-nitrogen interactions. Molecular Plant 3(6), 973-996.

Padhan BK, Sathee L, Jain V. 2020. Nitrogen remobilization and its importance in nitrogen use efficiency (NUE) of crops. Indian J. Agric. Sci. 90(12), 2251-2261.

Pangaribuan DH, Nurmauli N, Sengadji SF. 2017. The effect of enriched compost and nitrogen fertilizer on the growth and yield of sweet corn (Zea mays L.). Acta Hortic. 1152, 387-392.

Pangaribuan DH, Sarno S, Liliana Y, Bahriana S. 2020. Effects of chicken compost and KCl fertilizer on growth, yield, post-harvest quality of sweet corn, and soil health. Agrivita J. Agric. Sci. 42(1), 131-142.

Qiu NW, Jiang DC, Wang XS, Wang BS, Zhou F. 2019. Advances in the members and biosynthesis of the chlorophyll family. Photosynthetica 57(4), 974-984.

Ren H, Zhao M, Zhou B, Zhou W, Li K, Qi H, Jiang Y, Li C. 2022. Understanding the physiological mechanisms of variation in grain filling of maize under high planting density and varying nitrogen application rates. Front. Nutr. 9, 998946.

Sarjono A, Guntoro D, Supijatno S. 2018. The role of biomulch Arachis pintoi to increase soil infiltration rate and reduce erosion on sloping oil palm plantations. J. Tropic. Crop Sci. 5(3), 89-95.

Sarjono A, Guntoro D, Supijatno S. 2019. Comparing Arachis pintoi with other legume cover crops for erosion control in oil palm plantations. J. Agron. Indonesia 47(1), 90-96.

Standard Testing Center for Soil and Fertilizer Instrument, Ministry of Agriculture, Republic of Indonesia. 2023. Petunjuk Teknis Edisi 3 Analisis Kimia Tanah, Tanaman dan Pupuk. Ministry of Agriculture, Republic of Indonesia, Bogor.

Sundari T, Mutmaidah S, Baliadi Y. 2019. Keunggulan kompetitif agronomis dan ekonomis lima belas genotipe kedelai pada tumpangsari dengan jagung. Buletin Palawija 17(1), 46-56.

Suntari S, Ghulamahdi M, Melati M. 2023. Relay-Cropping soybean-maize in saturated soil culture increases efficiency of land use and nitrogen fertilizer. Indonesian J. Agron. 51(1), 91-100.

Sunuwar S, Siller A, Glaze-Corcoran S, Hashemi M. 2023. Cover crop termination method and N fertilization effect on sweet maize yield, quality, N uptake, and weed pressure. Nitrogen 4, 37-57.

Suwarto RA. 2021. Growth of legume cover crops under cassava and its effect on soil properties. Legume Res. 44(9), 1077-108.

Tan Y, Hu F, Chai Q, Li G, Coulter JA, Zhao C, Yu A, Fan Z, Yin E. 2020. Expanding row ratio with lowered nitrogen fertilization improves system productivity of maize/pea strip intercropping. European J. Agron. 113, 125986.

Teitzel JK, Peng CC. 1997. Centrocema Pubescens Benth. In Hanum IF, van der Maesen LJG (Eds.), Plant resources of South-East Asia No. 11 Auxiliary Plants. Backhuys Publishers, Leiden.

Turk M, Alagoz M. 2018. The effect of nitrogen fertilizer on yield and quality in sweet maize. Scientific Papers Series A. Agronomy 61(1), 408-411.

Ullah MI, Khakwani AA, Sadiq M, Awan I, Munir M, Ghazanfarullah G. 2015. Effects of nitrogen fertilization rates on growth, quality, and economic return of forage maize (Zea mays L.). Sarhad J. Agric. 31(1), 45-52.

Utomo R. 2020. Konservasi Hijauan Pakan dan Peningkatan Kualitas Bahan Pakan Berserat Tinggi. Cetakan Ketiga (Edisi Revisi). Gadjah Mada University Press, Yogyakarta.

Wang S, Guan K, Wang Z, Ainsworth EA, Zheng T, Townsend PA, Li K, Moller C, Wu G, Jiang C. 2021. Unique contributions of chlorophyll and nitrogen to predict photosynthetic capacity from leaf spectroscopy. J. Exp. Bot. 72(2), 341-354.

Wang Y, Zhang Y, Zhang H, Yang Z, Zhu Q, Yan B, Fei J, Rong X, Peng J, Lou G. 2022. Intercropping-driven nitrogen trade-off enhances maize productivity in a long-term experiment. Field Crops Res. 287, 108671.

Witte C. 2011. Urea metabolism in plants. Plant Sci. 180, 431-438.

Wu Y, Li Q, Jong R, Chen W, Liu X, Kong F, Kong Y, Shi H, Yuan J. 2019. Effect of low-nitrogen stress on photosynthesis and chlorophyll fluorescence characteristics of maize cultivars with different low-nitrogen tolerances. J. Integrative Agric. 18(6), 1246-1254.

Xu G, Fan X, Miller AJ. 2012. Plant nitrogen assimilation and use efficiency. Annu. Rev. Plant Biol. 63, 153-82.

Yemataw Z, Tawle K, Bolton M, Kebede R, Blomme G. 2018. Integration of shade-tolerant forage legumes under enset (Ensete ventricosum (Welw.) Cheesman) plants in Southwestern Ethiopia. Fruits Int. J. Tropical Subtropical Horticulture 73(60), 365-375.

Yuniarti Y, Chozin MA, Guntoro D, Murtilaksono KK. 2018. Perbandingan Arachis pintoi dengan jenis tanaman penutup tanah lain sebagai biomulsa di pertanaman kelapa sawit belum menghasilkan. J. Agron Indonesia 46(2), 215-221.

Zhang H, Shi W, Ali S, Chang S, Jia Q, Hou F. 2022. Legume/maize intercropping and N application for improved yield, quality, water, and N utilization for forage production. Agron. 122, 177.

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