EFFECTIVENESS OF BIOCHAR AND MICROBIAL APPLICATIONS IN SWEET SORGUM (SORGUM BICOLOR L.) CROPS ON SEAWATER-INTRUDED MEDIA
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Akbar Kurniawan
Rini Sulistiani
Dafni Mawar Tarigan
Wan Arfiani Barus
This study aims to determine the effect of biochar and microbial application on the growth and yield of sweet sorgum (Sorghum bicolor L.) in in seawater-intruded media. Biochar functions to improve soil structure and increase water retention and nutrient efficiency, while tobacco microbes have the potential to act as biological agents. The study employed a Split-Plot Design with two factors: biochar (0, 40, 80, 120 g/polybag) and microbes (0, 5, 10, 15 ml/polybag), each with three replications. Analysis results indicated that biochar application significantly influenced the parameters of seeds per panicle and seed weight per plot. The biochar treatment at a dose of 80 g/polybag produced the highest number of seeds per panicle at 74.54 seeds, while the treatment without biochar (B0) yielded the highest seed weight per plot at 57.65 g. The application of microorganisms and the interaction between biochar and microorganisms did not show a significant effect on all observed parameters. Biochar was proven effective in increasing sorghum yield on salt-intruded land through improved generative growth when applied at the optimal dose.
Agegnehu, G., Bass, A. M., Nelson, P. N., & Bird, M. I. (2016). Benefits of biochar, compost, and biochar–compost for soil quality, maize yield, and greenhouse gas emissions in a tropical agricultural soil. Science of the Total Environment, 543, 295–306.
Agustina, L. C. (2018). The Effect of N-Enriched Biochar Application on the Growth and Yield of Cassava (Manihot esculenta) and N Fertilizer Efficiency. Brawijaya University.
Alghamdi, A. G. (2018). Biochar as a potential soil additive for improving soil physical properties—a review. Arabian Journal of Geosciences, 11(24), 766.
Ali, M. A., Ilyas, F., Arshad, M., Hussain, S., Iqbal, M., Ahmad, S., Saboor, A., Mustafa, G., & Ahmed, N. (2019). Microbial inoculation of seeds for better plant growth and productivity. Priming and Pretreatment of Seeds and Seedlings: Implications for Plant Stress Tolerance and Enhancing Productivity in Crop Plants, 523–550.
Ameen, M., Mahmood, A., Shahzad, A. N., Zia, M. A., & Javaid, M. M. (2024). Sorghum’s potential unleashed: A comprehensive exploration of bio-energy production strategies and innovations. Bioresource Technology Reports, 27 (March). https://doi.org/10.1016/j.biteb.2024.101906
An-nafisa, A. (2023). Application of Organic Fertilizer from Agricultural Waste on Corn Growth and Yield in Alfisol Soil.
Artsam, A. F. A., Lukiwati, D. R., & Budiyanto, S. (2022). The Effect of Biochar and Soil-Improving Microorganisms Application on Peanut Production in Acidic Soils. JURNAL AGROPLASMA, 9(2), 137–149.
Ayumnuazmi, R., Fauzi, M. T., Sudharmawan, A. A. K., Sjah, T., & Wangiyana, W. (2025). The Potential of Plant Growth-Promoting Rhizobacteria from Mimosa Pudica Roots as a Biofertilizer in the "Agrokomplek Student Scientific Journal, 4(2), 364–369.
Azeem, M., Hayat, R., Hussain, Q., Ahmed, M., Pan, G., Tahir, M. I., Imran, M., & Irfan, M. (2019). Biochar improves soil quality and N2 fixation and reduces net ecosystem CO2 exchange in a dryland legume-cereal cropping system. Soil and Tillage Research, 186, 172–182.
Barus, W. A., Susanti, R., Khair, H., & Tarigan, D. M. (2023). Viability and responsiveness of several varieties of brown rice to salinity stress on a seedbed. IOP Conference Series: Earth and Environmental Science, 1228(1), 12028.
Batista, B. D., Bonatelli, M. L., & Quecine, M. C. (2021). Fast screening of bacteria for plant growth- promoting traits. The Plant Microbiome: Methods and Protocols, 61–75.
Battong, U., Sari, K. R., & Nasrah, N. (2020). The Effect of Concentrations of Nasa Liquid Organic Fertilizer and the Application of Organic Mulch on the Growth and Yield of Red Onions (Allium cepa L.). AGROVITAL: Journal of Agricultural Science, 5(1), 21–24.
Ginting, A. Y. (2024). The Effect Of Cow Manure Bokashi Application On Some Physical Properties Of Ultisol And Soybean (Glycine max (L.) merril) YIELD. UNIVERSITY OF JAMBI.
Hasibuan, S. P., Febjislami, S., & Suliansyah, I. (2022). The Effect of Chicken Manure on the Growth and Seed Quality of Sorghum (Sorghum bicolor L.). Journal of Precision Agriculture, 6(1), 15– 27.
Hoque, M. N., Imran, S., Hannan, A., Paul, N. C., Mahamud, M. A., Chakrobortty, J., Sarker, P., Irin, I. J., Brestic, M., & Rhaman, M. S. (2022). Organic amendments for mitigation of salinity stress in plants: A review. Life, 12(10), 1632.
Ibrahim, M. E. H., Ali, A. Y. A., Elsiddig, A. M. I., Zhou, G., Nimir, N. E. A., Agbna, G. H., & Zhu,G. (2021). Mitigation effect of biochar on sorghum seedling growth under salinity stress. Pak. J. Bot, 53(2), 387–392.
Ilahi, R. P., & Sefano, M. A. (2025). The Effect of the Residual Combination of Rice Husk Biochar and Dolomite on Nitrogen Leaching in Maize (Zea Mays L.) Cultivation. Journal Arunasita, 2(2), 103–113.
Kartinaty, T., Halono, J. D., & Puspitasari, M. (2019). Agronomic characteristics of three corn varieties and fertilizer rates in a intercropping system on dryland. Hijau Cendekia Scientific Journal, 4(2), 78–86.
Kusvuran, A., Bilgici, M., & Kusvuran, S. (2021). Maydica. May.
Lehmann, J., & Joseph, S. (2024). Biochar for environmental management: science, technology, and implementation. Taylor & Francis.
Lubis, K. S., & Hidayat, B. (2019). Phosphorus nutrient availability resulting from the application of rice husk biochar and cattle manure on Kuala Bekala Inceptisol. Jurnal Online Pertanian Tropik, 6(2), 287–293.
Malik, S., Syakur, S., & Darusman, D. (2022). The Effect of Several Types of Biochar on the Growth and Nutrient Uptake of Soybean Plants (Glycine max L. Merr). Student Journal of Agricultural Science, 7(1), 654–661.
Mashamaite, C. V., Motsi, H., Manyevere, A., & Poswa, S. B. (2024). Assessing the potential of biochar as a viable alternative to synthetic fertilizers in sub-Saharan African smallholder farming: a review. Agronomy, 14(6), 1215.
Momongan, J. D., Trikoesoemaningtyas, T., Wirnas, D., & Sopandie, D. (2019). Yield potential and tolerance of sorghum inbred lines on phosphorus-deficient soils. Indonesian Journal of Agronomy (, 47(1), 39–46.
Nabi, M. (2023). Role of microorganisms in plant nutrition and soil health. In Sustainable plant nutrition (pp. 263–282). Elsevier.
Nehela, Y., Mazrou, Y. S. A., Alshaal, T., Rady, A. M. S., El-Sherif, A. M. A., Omara, A. E.-D., Abd El-Monem, A. M., & Hafez, E. M. (2021). The integrated amendment of sodic-saline soils using biochar and plant growth-promoting rhizobacteria enhances maize (Zea mays L.) resilience to water salinity. Plants, 10(9), 1960.
Patani, A., Prajapati, D., Singh, S., Enakiev, Y., Bozhkov, S., Jabborova, D., & Joshi, C. (2023). Beneficial effects of biochar application on mitigating the implications of drought and salinity stress on plants. Plant Sci. Today, 10, 188–193.
Rahman, A., Anugrahwati, D. R., & Zubaidi, A. (2022). Yield Potential Test of Several Sorghum (Sorghum bicolor L. Moench) Genotypes on Dryland in North Lombok. Agrokomplek Student Scientific Journal, 1(2), 164–171.
Rifki, G. Y., Ilyas, I., & Khalil, M. (2022). Effects of Coconut Husk Biochar Application on the Chemical Properties of Ultisols and Maize (Zea mays) Growth. Agricultural Student Scientific Journal, 7(3), 422–430.
Rizvi, A., Ahmed, B., Khan, M. S., Umar, S., & Lee, J. (2021). Psychrophilic bacterial phosphate- biofertilizers: a novel extremophile for sustainable crop production under cold environments. Microorganisms, 9(12), 2451.
Rochman, A., Maryanto, J., & Herliana, O. (2021). Nitrogen and phosphorus uptake and soybean (Glycine max (L.) Merrill) yield in Alfisol soil following the application of biochar and vermicompost. Buletin Palawija, 19(1), 22–30.
Soare, E., Chiurciu, I.-A., Apostol, C.-E., Bălan, A.-V., & Fulgeanu, D.-F. (2024). Research On Worldwide Sorghum Production And Trade For The Period 2017–2022. Scientific Papers Series: Management, Economic Engineering in Agriculture & Rural Development, 24(4).
Suryantini, S. (2017). Formulation of a carrier material for phosphate-solubilizing biofertilizer for soybeans in acidic soil. Buletin Palawija, 14(1), 28–35.
Tarigan, D. M., Barus, W. A., Munar, A., & Lestami, A. (2024). Sorghum Cultivation Techniques in Saline Soils. umsu press.
Tarigan, D. M., & Ismuhadi, I. (2021). Morphological Characteristics and Yield of Sweet Sorghum (Sorghum bicolor (L.) Moench) Treated with Palm Oil Mill Effluent and KCl on Converted Oil Palm Land. AGRIUM: Journal of Agricultural Science, 24(1), 22–27.
Tarigan, J. A., Zuhry, E., & Nurbaiti, N. (2015). Yield Potential Test of Several Sweet Sorghum (Sorghum bicolor (L.) Moench) Genotypes from the Batan Collection. Riau University.
Ullah, Z., Ali, S., Muhammad, N., Khan, N., Rizwan, M., Khan, M. D., Khan, N., Khattak, B., Alhaithloul, H. A. S., & Soliman, M. H. (2020). Biochar impact on microbial population and elemental composition of red soil. Arabian Journal of Geosciences, 13, 1–9.
Wortel, M. T. (2023). Evolutionary coexistence in a fluctuating environment through specialization at the resource level. Journal of Evolutionary Biology, 36(3), 622–631.
Zustika, S., & Akbar, H. (2025). The Use Of Various Types And Doses Of Biochar On Carbon Dioxide, Nitrate, And Microorganism Emissions In Soil. Journal of Soil and Land Resources, 12(1), 89–96.
