Research Article
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Year 2024, Volume: 13 Issue: 3, 179 - 189, 25.06.2024
https://doi.org/10.18393/ejss.1432873

Abstract

References

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  • Al-Suhaibani, N., Selim, M., Alderfasi, A., El-Hendawy, S., 2020. Comparative performance of integrated nutrient management between composted agricultural wastes, chemical fertilizers, and biofertilizers in improving soil quantitative and qualitative properties and crop yields under arid conditions. Agronomy 10(10): 1503.
  • Arthanawa, I.G.N., Astika, I.N., Darmawan, I.K., Yana, D.P.S., Situmeang, Y.P., Sudita, I.D.N., 2022. The effects of organic and inorganic fertilizers on red chili plants. SEAS (Sustainable Environment Agricultural Science) 6(1): 70–80.
  • Arumugam, V., Abdullah, I., Yusoff, I.S.M., Abdullah, N.L., Tahir, R.M., Nasir, A.M., Omar, A.E., Ismail, M.H., 2021. The impact of COVID-19 on solid waste generation in the perspectives of socioeconomic and people’s behavior: A case study in Serdang, Malaysia. Sustainability 13(23): 13045.
  • Asghar, W., Kataoka, R., 2021. Effect of coapplication of Trichoderma spp. with organic composts on plant growth enhancement, soil enzymes and fungal community in soil. Archives of Microbiology 203(7): 4281–4291.
  • Baldi, E., Amadei, P., Pelliconi, F., Tosell, M., 2016. Use of Trichoderma spp. and arbuscular mycorrhizal fungi to increase soil beneficial population of bacteria in a nectarine commercial orchard: Effect on root growth, nutrient acquisition and replanting disease. Journal of Plant Nutrition 39(8): 1147–1155.
  • Beeby, J., Moore, S., Taylor, L., Nderitu, S., 2020. Effects of a one-time organic fertilizer application on long-term crop and residue yields, and soil quality measurements using biointensive agriculture. Frontiers in Sustainable Food Systems 4: 67.
  • Bhandari, S., Pandey, K.R., Joshi, Y.R., Lamichhane, S.K., 2021. An overview of multifaceted role of Trichoderma spp. for sustainable agriculture. Archives of Agriculture and Environmental Science 6(1): 72–79.
  • Bhardwaj, D., Ansari, M.W., Sahoo, R.K., Tuteja, N., 2014. Biofertilizers function as key player in sustainable agriculture by improving soil fertility, plant tolerance and crop productivity. Microbial Cell Factories 13(1): 1–10.
  • Bononi, L., Chiaramonte, J.B., Pansa, C.C., Moitinho, M.A., Melo, I.S., 2020. Phosphorus-solubilizing Trichoderma spp. from Amazon soils improve soybean plant growth. Scientific Reports 10: 2858. Chantal, K., Xiaohou, S., Weimu, W., Iro Ong’or, B.T., 2010. Effects of effective microorganisms on yield and quality of vegetable cabbage comparatively to nitrogen and phosphorus fertilizers. Pakistan Journal of Nutrition 9(11): 1039–1042.
  • Contreras-Cornejo, H.A., Macías-Rodríguez, L., Del-Val, E., Larsen, J., 2016. Ecological functions of Trichoderma spp. and their secondary metabolites in the rhizosphere: interactions with plants. FEMS Microbiology Ecology 92(4): fiw036.
  • Darwin, M., Mamondol, M.R., Sormin, S.A., Nurhayati, Y., Tambunan, H., Sylvia, D., Adnyana, I.M.D.M., Prasetiyo, B., Vianitati, P., Gebang, A.A., 2021. Quantitative approach research method, 1st ed. CV Media Sains Indonesia, Bandung. 178p.
  • Dehghani, M.H., Omrani, G.A., Karri, R.R., 2021. Solid waste-sources, toxicity, and their consequences to human health. In: Soft computing techniques in solid waste and wastewater management. Karri, R.R., Ravindran, G., Dehghani, M.H. (Eds.). Elsevier, pp. 205–213.
  • Du, C., Munir, S., Abad, R., Lu, D., 2020. Valorization of organic waste into biofertilizer and its field application. In: Waste Biorefinery. Bhasbar, T., Pandey, A., Tsang, D.C.W. (Eds.). Elsevier, pp. 179–198.
  • El-Ramady, H., Brevik, E., Amer, M., Elsakhawy, T., Omara Ahmed, A.E.-D., Elbasiouny, H., Elbehiry, F., Mosa, A., El-Ghamry, A., Bayoumi, Y., Shalaby, T., 2020. Soil and air pollution in the era of COVID-19: A global issue. Egyptian Journal of Soil Science 60(4): 437–448.
  • Eugenio, N.R., McLaughlin, M., Pennock, D., 2018. Soil pollution: a hidden reality. Food and Agriculture Organization of the United Nations (FAO), Rome. 142p. Available at Access date: 13.04.2022: https://www.fao.org/3/i9183en/i9183en.pdf
  • Fasusi, O.A., Cruz, C., Babalola, O.O., 2021. Agricultural sustainability: Microbial biofertilizers in rhizosphere management. Agriculture 11(2): 163.
  • Fitriatin, B.N., Amanda, A.P., Kamaluddin, N.N., Khumairah, F.H., Sofyan, E.T., Yuniarti, A., Turmuktini, T., 2021. Some soil biological and chemical properties as affected by biofertilizers and organic ameliorants application on paddy rice. Eurasian Journal of Soil Science 10(2): 105–110.
  • Francioli, D., Schulz, E., Lentendu, G., Wubet, T., Buscot, F., Reitz, T., 2016. Mineral vs. organic amendments: Microbial community structure, activity and abundance of agriculturally relevant microbes are driven by long-term fertilization strategies. Frontiers in Microbiology 7(1446): 1–16.
  • Geisseler, D., Scow, K.M., 2014. Long-term effects of mineral fertilizers on soil microorganisms - A review. Soil Biology and Biochemistry 75: 54–63.
  • Halifu, S., Deng, X., Song, X., Song, R., 2019. Effects of two Trichoderma strains on plant growth, rhizosphere soil nutrients, and fungal community of Pinus sylvestris var. mongolica annual seedlings. Forests 10(9): 758.
  • Hidalgo, D., Corona, F., Martín-Marroquín, J.M., 2022. Manure biostabilization by effective microorganisms as a way to improve its agronomic value. Biomass Conversion and Biorefinery 12(10): 4649–4664.
  • Islam, M.A., Mostafa, M.G., Rahman, M.R., 2014. Conversion of solid organic waste into compost using Trichoderma spp. And its application on some selected vegetables. International Journal of Environment and Waste Management 14(3): 211–221.
  • Kai, T., Tamaki, M., 2020. Effect of organic and chemical fertilizer application on growth, yield, and soil biochemical properties of landrace Brassica napus L. leaf-and-stem vegetable and landrace (Norabona). Journal of Agricultural Chemistry and Environment 9(4): 314–330.
  • Kashyap, P.L., Rai, P., Srivastava, A.K., Kumar, S., 2017. Trichoderma for climate resilient agriculture. World Journal of Microbiology and Biotechnology 33(155): 1–18.
  • Lazcano, C., Zhu-Barker, X., Decock, C., 2021. Effects of organic fertilizers on the soil microorganisms responsible for N2O emissions: A review. Microorganisms 9(5): 983.
  • Li, S., Li, J., Zhang, B., Li, D., Li, G., Li, Y., 2017. Effect of different organic fertilizers application on growth and environmental risk of nitrate under a vegetable field. Scientific Reports 7: 17020.
  • Mącik, M., Gryta, A., Frąc, M., 2020. Biofertilizers in agriculture: An overview on concepts, strategies and effects on soil microorganisms. In: Advances in Agronomy. Sparks, D.L. (Ed.). Vol. 162. Elsevier, pp. 31–87.
  • Mahanty, T., Bhattacharjee, S., Goswami, M., Bhattacharyya, P., Das, B., Ghosh, A., Tribedi, P., 2016. Biofertilizers: a potential approach for sustainable agriculture development. Environmental Science and Pollution Research 24: 1–21.
  • Malusá, E., Sas-Paszt, L., Ciesielska, J., 2012. Technologies for beneficial microorganisms inocula used as biofertilizers. The Scientific World Journal Article ID 491206.
  • Mayo-Prieto, S., Porteous-Álvarez, A.J., Mezquita-García, S., Rodríguez-González, Á., Carro-Huerga, G., del Ser-Herrero, S., Gutiérrez, S., Casquero, P.A., 2021. Influence of physicochemical characteristics of bean crop soil in Trichoderma spp. development. Agronomy 11(2): 274.
  • Mehetre, S.T., Mukherjee, P.K., 2015. Trichoderma improves nutrient use efficiency in crop plants. In: Nutrient use efficiency: from basics to advances. Rakshit, A., Singh, H.B., Sen, A.. (Eds.). Springer India. pp. 173–180.
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  • Ministry of Environment and Forestry, 2022. National Waste Management Information System. pp.14-50. Available at Access date: 13.04.2022: https://sipsn.menlhk.go.id/sipsn/public/data/timbulan
  • Ministry of Environment and Forestry, 2020. Status of Environment and Forestry 2020. Ministry of Environment and Forestry of the Republic of Indonesia. Available at Access date: 13.04.2022: https://www.menlhk.go.id/cadmin/uploads/SLHI_2022_upload_final_77f9948571.pdf
  • Mitter, E.K., Tosi, M., Obregón, D., Dunfield, K.E., Germida, J.J., 2021. Rethinking Crop Nutrition in Times of Modern Microbiology: Innovative Biofertilizer Technologies. Frontiers in Sustainable Food Systems 5: 606815.
  • National Standardization Agency of the Republic of Indonesia, 2004. Indonesian National Standard 19-7030-2004 concerning Specifications of compost from domestic organic waste. Available at Access date: 13.04.2022: http://inswa.or.id/wp-content/uploads/2012/07/Spesifikasi-kompos-SNI.pdf
  • Pandey, V., Chandra, K., 2016. Agriculturally important microorganisms as biofertilizers: commercialization and regulatory requirements in Asia. In: Agriculturally important microorganisms. Singh, H.B., Sarma, B.K., Keswani, C. (Eds.). Springer Singapore. pp. 133–145.
  • Pappalardo, G., Cerroni, S., Nayga, R.M., Yang, W., 2020. Impact of COVID-19 on Household Food Waste: The Case of Italy. Frontiers in Nutrition 7: 585090.
  • Putro, B.D., 2020. Double burdens: the condition of woman scavengers during the pandemic at the monang maning waste processing site, Denpasar. Journal of Bali Studies 10(2): 537–556.
  • Raimi, A., Adeleke, R., Roopnarain, A., 2017. Soil fertility challenges and biofertilizer as a viable alternative for increasing smallholder farmer crop productivity in sub-Saharan Africa. Cogent Food and Agriculture 3(1): 1400933.
  • Rashid, M.I., Mujawar, L.H., Shahzad, T., Almeelbi, T., Ismail, I.M.I., Oves, M., 2016. Bacteria and fungi can contribute to nutrients bioavailability and aggregate formation in degraded soils. Microbiological Research 183: 26–41.
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Efficacy of solid and liquid Biolistics in improving the nutrients in latosol soil from Bali, Indonesia

Year 2024, Volume: 13 Issue: 3, 179 - 189, 25.06.2024
https://doi.org/10.18393/ejss.1432873

Abstract

The increase in household organic waste during the COVID-19 pandemic was a source of pollution, especially in soil. The high pollution intensity in various sectors causes the soil to degrade and lose nutrients. This study aimed to analyze the efficacy of solid and liquid biolistics for improving the nutritional status of latosol soil collected from Bali, Indonesia. The experimental design was a completely randomized design. Efficacy testing by providing solid and liquid biolistics to latosol soils in polybags at different concentrations was performed five times. Macro- and micronutrient testing was carried out three months after the application of the treatments. One-way ANOVA and the LSD test (p<0.05) were used to assess the results. The results revealed significant differences between the treatment groups in terms of N, P, K, the C/N ratio, water content, and pH, with a probability value of 0.000 (p<0.05). Thus, solid and liquid biolistics are efficacious at increasing the fertility of latosol soils. The contents of N, P, K, moisture content, pH, macronutrients (P2O5, K2O, C-Organic, N-Total, and C/N ratio) and micronutrients (Fe, Mg, Mn, Na, Zn) contribute significantly to improving soil aggregates and structures; improving the physical, chemical, and biological properties of the soil; and improving the bioavailability of nutrients and soil quality. The presence of microorganisms is involved in accelerating the process of biodegradation and decomposition in soil. Thus, solid and liquid biolistics deserve to be developed as natural soil repairers.

References

  • Abbasi, M.K., Yousra, M., 2012. Synergistic effects of biofertilizer with organic and chemical N sources in improving soil nutrient status and increasing growth and yield of wheat grown under greenhouse conditions. Plant Biosystems 146: 181–189.
  • Adnan, M., Xiao, B., Xiao, P., Zhao, P., Bibi, S., 2022. Heavy metal, waste, COVID-19, and rapid industrialization in this modern era-fit for sustainable future. Sustainability 14(8): 4746.
  • Adnyana, I.M.D.M., 2021. Populasi dan Sampel. In: Metode penelitian pendekatan kuantitatif. Darwin, M. (Ed.), CV. Media Sains Indonesia, Bandung, pp. 103–116.
  • Al-Suhaibani, N., Selim, M., Alderfasi, A., El-Hendawy, S., 2020. Comparative performance of integrated nutrient management between composted agricultural wastes, chemical fertilizers, and biofertilizers in improving soil quantitative and qualitative properties and crop yields under arid conditions. Agronomy 10(10): 1503.
  • Arthanawa, I.G.N., Astika, I.N., Darmawan, I.K., Yana, D.P.S., Situmeang, Y.P., Sudita, I.D.N., 2022. The effects of organic and inorganic fertilizers on red chili plants. SEAS (Sustainable Environment Agricultural Science) 6(1): 70–80.
  • Arumugam, V., Abdullah, I., Yusoff, I.S.M., Abdullah, N.L., Tahir, R.M., Nasir, A.M., Omar, A.E., Ismail, M.H., 2021. The impact of COVID-19 on solid waste generation in the perspectives of socioeconomic and people’s behavior: A case study in Serdang, Malaysia. Sustainability 13(23): 13045.
  • Asghar, W., Kataoka, R., 2021. Effect of coapplication of Trichoderma spp. with organic composts on plant growth enhancement, soil enzymes and fungal community in soil. Archives of Microbiology 203(7): 4281–4291.
  • Baldi, E., Amadei, P., Pelliconi, F., Tosell, M., 2016. Use of Trichoderma spp. and arbuscular mycorrhizal fungi to increase soil beneficial population of bacteria in a nectarine commercial orchard: Effect on root growth, nutrient acquisition and replanting disease. Journal of Plant Nutrition 39(8): 1147–1155.
  • Beeby, J., Moore, S., Taylor, L., Nderitu, S., 2020. Effects of a one-time organic fertilizer application on long-term crop and residue yields, and soil quality measurements using biointensive agriculture. Frontiers in Sustainable Food Systems 4: 67.
  • Bhandari, S., Pandey, K.R., Joshi, Y.R., Lamichhane, S.K., 2021. An overview of multifaceted role of Trichoderma spp. for sustainable agriculture. Archives of Agriculture and Environmental Science 6(1): 72–79.
  • Bhardwaj, D., Ansari, M.W., Sahoo, R.K., Tuteja, N., 2014. Biofertilizers function as key player in sustainable agriculture by improving soil fertility, plant tolerance and crop productivity. Microbial Cell Factories 13(1): 1–10.
  • Bononi, L., Chiaramonte, J.B., Pansa, C.C., Moitinho, M.A., Melo, I.S., 2020. Phosphorus-solubilizing Trichoderma spp. from Amazon soils improve soybean plant growth. Scientific Reports 10: 2858. Chantal, K., Xiaohou, S., Weimu, W., Iro Ong’or, B.T., 2010. Effects of effective microorganisms on yield and quality of vegetable cabbage comparatively to nitrogen and phosphorus fertilizers. Pakistan Journal of Nutrition 9(11): 1039–1042.
  • Contreras-Cornejo, H.A., Macías-Rodríguez, L., Del-Val, E., Larsen, J., 2016. Ecological functions of Trichoderma spp. and their secondary metabolites in the rhizosphere: interactions with plants. FEMS Microbiology Ecology 92(4): fiw036.
  • Darwin, M., Mamondol, M.R., Sormin, S.A., Nurhayati, Y., Tambunan, H., Sylvia, D., Adnyana, I.M.D.M., Prasetiyo, B., Vianitati, P., Gebang, A.A., 2021. Quantitative approach research method, 1st ed. CV Media Sains Indonesia, Bandung. 178p.
  • Dehghani, M.H., Omrani, G.A., Karri, R.R., 2021. Solid waste-sources, toxicity, and their consequences to human health. In: Soft computing techniques in solid waste and wastewater management. Karri, R.R., Ravindran, G., Dehghani, M.H. (Eds.). Elsevier, pp. 205–213.
  • Du, C., Munir, S., Abad, R., Lu, D., 2020. Valorization of organic waste into biofertilizer and its field application. In: Waste Biorefinery. Bhasbar, T., Pandey, A., Tsang, D.C.W. (Eds.). Elsevier, pp. 179–198.
  • El-Ramady, H., Brevik, E., Amer, M., Elsakhawy, T., Omara Ahmed, A.E.-D., Elbasiouny, H., Elbehiry, F., Mosa, A., El-Ghamry, A., Bayoumi, Y., Shalaby, T., 2020. Soil and air pollution in the era of COVID-19: A global issue. Egyptian Journal of Soil Science 60(4): 437–448.
  • Eugenio, N.R., McLaughlin, M., Pennock, D., 2018. Soil pollution: a hidden reality. Food and Agriculture Organization of the United Nations (FAO), Rome. 142p. Available at Access date: 13.04.2022: https://www.fao.org/3/i9183en/i9183en.pdf
  • Fasusi, O.A., Cruz, C., Babalola, O.O., 2021. Agricultural sustainability: Microbial biofertilizers in rhizosphere management. Agriculture 11(2): 163.
  • Fitriatin, B.N., Amanda, A.P., Kamaluddin, N.N., Khumairah, F.H., Sofyan, E.T., Yuniarti, A., Turmuktini, T., 2021. Some soil biological and chemical properties as affected by biofertilizers and organic ameliorants application on paddy rice. Eurasian Journal of Soil Science 10(2): 105–110.
  • Francioli, D., Schulz, E., Lentendu, G., Wubet, T., Buscot, F., Reitz, T., 2016. Mineral vs. organic amendments: Microbial community structure, activity and abundance of agriculturally relevant microbes are driven by long-term fertilization strategies. Frontiers in Microbiology 7(1446): 1–16.
  • Geisseler, D., Scow, K.M., 2014. Long-term effects of mineral fertilizers on soil microorganisms - A review. Soil Biology and Biochemistry 75: 54–63.
  • Halifu, S., Deng, X., Song, X., Song, R., 2019. Effects of two Trichoderma strains on plant growth, rhizosphere soil nutrients, and fungal community of Pinus sylvestris var. mongolica annual seedlings. Forests 10(9): 758.
  • Hidalgo, D., Corona, F., Martín-Marroquín, J.M., 2022. Manure biostabilization by effective microorganisms as a way to improve its agronomic value. Biomass Conversion and Biorefinery 12(10): 4649–4664.
  • Islam, M.A., Mostafa, M.G., Rahman, M.R., 2014. Conversion of solid organic waste into compost using Trichoderma spp. And its application on some selected vegetables. International Journal of Environment and Waste Management 14(3): 211–221.
  • Kai, T., Tamaki, M., 2020. Effect of organic and chemical fertilizer application on growth, yield, and soil biochemical properties of landrace Brassica napus L. leaf-and-stem vegetable and landrace (Norabona). Journal of Agricultural Chemistry and Environment 9(4): 314–330.
  • Kashyap, P.L., Rai, P., Srivastava, A.K., Kumar, S., 2017. Trichoderma for climate resilient agriculture. World Journal of Microbiology and Biotechnology 33(155): 1–18.
  • Lazcano, C., Zhu-Barker, X., Decock, C., 2021. Effects of organic fertilizers on the soil microorganisms responsible for N2O emissions: A review. Microorganisms 9(5): 983.
  • Li, S., Li, J., Zhang, B., Li, D., Li, G., Li, Y., 2017. Effect of different organic fertilizers application on growth and environmental risk of nitrate under a vegetable field. Scientific Reports 7: 17020.
  • Mącik, M., Gryta, A., Frąc, M., 2020. Biofertilizers in agriculture: An overview on concepts, strategies and effects on soil microorganisms. In: Advances in Agronomy. Sparks, D.L. (Ed.). Vol. 162. Elsevier, pp. 31–87.
  • Mahanty, T., Bhattacharjee, S., Goswami, M., Bhattacharyya, P., Das, B., Ghosh, A., Tribedi, P., 2016. Biofertilizers: a potential approach for sustainable agriculture development. Environmental Science and Pollution Research 24: 1–21.
  • Malusá, E., Sas-Paszt, L., Ciesielska, J., 2012. Technologies for beneficial microorganisms inocula used as biofertilizers. The Scientific World Journal Article ID 491206.
  • Mayo-Prieto, S., Porteous-Álvarez, A.J., Mezquita-García, S., Rodríguez-González, Á., Carro-Huerga, G., del Ser-Herrero, S., Gutiérrez, S., Casquero, P.A., 2021. Influence of physicochemical characteristics of bean crop soil in Trichoderma spp. development. Agronomy 11(2): 274.
  • Mehetre, S.T., Mukherjee, P.K., 2015. Trichoderma improves nutrient use efficiency in crop plants. In: Nutrient use efficiency: from basics to advances. Rakshit, A., Singh, H.B., Sen, A.. (Eds.). Springer India. pp. 173–180.
  • Ministry of Agriculture, 2019. Regulation of the Minister of Agriculture of the Republic of Indonesia Number 01 of 2019 concerning Registration of Organic Fertilizers, Biological Fertilizers, and Soil Improvements. pp. 1-44.
  • Ministry of Environment and Forestry, 2022. National Waste Management Information System. pp.14-50. Available at Access date: 13.04.2022: https://sipsn.menlhk.go.id/sipsn/public/data/timbulan
  • Ministry of Environment and Forestry, 2020. Status of Environment and Forestry 2020. Ministry of Environment and Forestry of the Republic of Indonesia. Available at Access date: 13.04.2022: https://www.menlhk.go.id/cadmin/uploads/SLHI_2022_upload_final_77f9948571.pdf
  • Mitter, E.K., Tosi, M., Obregón, D., Dunfield, K.E., Germida, J.J., 2021. Rethinking Crop Nutrition in Times of Modern Microbiology: Innovative Biofertilizer Technologies. Frontiers in Sustainable Food Systems 5: 606815.
  • National Standardization Agency of the Republic of Indonesia, 2004. Indonesian National Standard 19-7030-2004 concerning Specifications of compost from domestic organic waste. Available at Access date: 13.04.2022: http://inswa.or.id/wp-content/uploads/2012/07/Spesifikasi-kompos-SNI.pdf
  • Pandey, V., Chandra, K., 2016. Agriculturally important microorganisms as biofertilizers: commercialization and regulatory requirements in Asia. In: Agriculturally important microorganisms. Singh, H.B., Sarma, B.K., Keswani, C. (Eds.). Springer Singapore. pp. 133–145.
  • Pappalardo, G., Cerroni, S., Nayga, R.M., Yang, W., 2020. Impact of COVID-19 on Household Food Waste: The Case of Italy. Frontiers in Nutrition 7: 585090.
  • Putro, B.D., 2020. Double burdens: the condition of woman scavengers during the pandemic at the monang maning waste processing site, Denpasar. Journal of Bali Studies 10(2): 537–556.
  • Raimi, A., Adeleke, R., Roopnarain, A., 2017. Soil fertility challenges and biofertilizer as a viable alternative for increasing smallholder farmer crop productivity in sub-Saharan Africa. Cogent Food and Agriculture 3(1): 1400933.
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There are 57 citations in total.

Details

Primary Language English
Subjects Plant Nutrition and Soil Fertility, Soil Sciences and Plant Nutrition (Other)
Journal Section Articles
Authors

Ni Luh Gede Sudaryati This is me 0000-0003-3716-5215

I Made Dwi Mertha Adnyana

Publication Date June 25, 2024
Published in Issue Year 2024 Volume: 13 Issue: 3

Cite

APA Sudaryati, N. L. G., & Mertha Adnyana, I. M. D. (2024). Efficacy of solid and liquid Biolistics in improving the nutrients in latosol soil from Bali, Indonesia. Eurasian Journal of Soil Science, 13(3), 179-189. https://doi.org/10.18393/ejss.1432873