Sugarcane leaf litter biomass and its effects on increasing sugarcane drought stress tolerance and reducing CO₂ emissions
Donny Nugroho Kalbuadi(1*), Siswanto Siswanto(2), Happy Widiastuti(3)
(1) Indonesian Oil Palm Research Institute, Bogor Unit
(2) Indonesian Oil Palm Research Institute, Bogor Unit
(3) Indonesian Oil Palm Research Institute, Bogor Unit
(*) Corresponding Author
Abstract
Burning biomass on sugarcane plantations can lead to pollution (CO₂ emissions) and degradation in soil properties. Adopting non-burning technology can increase the value of biomass by applying it directly to the soil, although this may result in nutrient immobilization, which can hinder optimal plant growth due to high lignin and cellulose content or high CN ratio. On the contrary, composting waste with a decomposer will boost plant nutrient availability and enhance other soil characteristics. This research was aimed to assess the effect of several types of sugarcane organic matter on improving soil characteristics, growth of sugarcane and the CO₂ emissions. The study was conducted using a Completely Randomized Factorial Design with two factors: type of organic matter (control, fresh litter and compost of sugarcane biomass) and level of drought stress (100, 75, 50 and 25%). Incubation occurred over 16 weeks, divided into two phases of 8 weeks each. The results showed that the application of organic materials in the form of compost could reduce water loss caused by environmental heat and sugarcane growing process. Furthermore, compost application improved soil chemical and biological properties by increasing soil pH, total nitrogen (N), total phosphate (P), total potassium (K), and the total microbial population, although differences were not significant compared to the control. Additionally, applying organic matter in the form of compost or litter helped suppress or reduce emissions, with compost treatment proving more effective than litter in reducing CO₂ emissions.
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Abel, S., Peters, A., Trinks, S., Schonsky, H., Facklam, M., and Wessolek, G. (2013). Impact of biochar and hydrochar addition on water retention and water repellency of sandy soil. Geoderma, 202–203, pp. 183–191.
Adugna, G. (2016). A review on impact of compost on soil properties, water use and crop productivity. Acad. Res. J. Agri. Sci. Res., 4(3), pp. 93–104.
Alvarez, V., Rosas, F., Reyes, M., Murillo, J., De La Rosa, N., Arzaluz, M., Lara, J., and Cardoso, G. (2018). Sugarcane burning emissions: Characterization and emission factors. Atmospheric Environment, 193, pp. 262–272.
Barakat, M., El-Kosary, S., Borhan, T., and Abd-Al Nafea, M. (2015). Effect of hydrogel soil addition under different irrigation levels on grandnain bannana plants. Journal of Horticultural Science and Ornamental Plants, 7(1), pp. 18–28.
Batubara, R., and Listyarini, E. (2017). Kajian aplikasi seresah tebu dan urea terhadap ketersediaan nitrogen dalam tanah PT Perkebunan Nusantara X Jengkol, Kediri. Jurnal Tanah dan Sumberdaya Lahan, 4(1), pp. 411–419.
Bruun, E., Petersen, C., Hansen, E., Holm, J., and Hauggaard-Nielsen, H. (2014). Biochar amendment to coarse sandy subsoil improves root growth and increases water retention. Soil Use and Management, 30, pp. 109–118.
Cai, Z., Xu, M., Wang, B., Zhang, L., Wen, S., and Gao, S. (2018). Effectiveness of crop straws, and swine manure in ameliorating acidic red soils: a laboratory study. Journal of Soils and Sediments, 18(9), pp. 2893–2903.
Chacha, M., Andrew, B., and Vegi, M. (2019). Amandment of Soil Water Retention and Nutrients Holding Capacity by Using Sugarcane Bagasse. Curr. Agri. Res., 7(2), pp. 224–235.
Hamed, M., Desoky, M., Ghallab, A., and Faragallah, M. (2014). Effect of Incubation Periods and Some Organic Materials On Phosphorus Forms In Calcareous Soils. International Journal Of Technology Enhancements And Emerging Engineering Research, 2(6), pp. 2347–4289.
Hariyono, B., Utomo, W., Utami, S., and Islami, T. (2020). Utilization of the trash biochar and waste of sugarcane to improve the quality of sandy soil and growth of sugarcane. IOP Conf. Ser.: Earth Environ. Sci., 418, 012067.
Haynes, R., and Graham, M. (2004). Composition of the soil microbial community under sugarcane production as indicated by phospholipid fatty acid analysis. Proc S Afr Sug Technol Ass, 78.
Ho, T., Tra, T., Le, T., Nguyen, N., Tran, C., Nguyen, P., Vo, T., Thai, V., and Bui X. (2022). Compost to improve sustainable soil cultivation and crop productivity. Case Studies in Chemical and Environmental Engineering, 6, 100211.
Iqbal. (2018). Effect of Sugarcane Litter Compost on Soil Compaction. International Journal of Agriculture System, 6(1), 35–44.
Liu, X., Shi, Y., Kong, L., Tong, L., Cao, H., Zhou, H., and Lv, Y. (2022). Long-term application of bio-compost increased soil microbial community diversity and altered its composition and network. Microorganisms, 10, 462.
Luo, Y., and Zhou, X. (2006). Soil respiration and the environment, CHAPTER 3 - Processes of CO₂ Production in Soil. Academic Press, pp. 35–59.
Mashoko, L., Mbohwa, C., and Thomas, V. (2010). LCA of the South African sugar industry. Journal of Environmental Planning and Management, 53(6), pp. 793–807.
Mastur. (2006). Respon Fisiologis Tanaman Tebu Terhadap Kekeringan. Buletin Tanaman Tembakau, Serat & Minyak Industri, 8(2), pp. 98–111.
Moitinho, M., Ferraudo, A., Panosso, A., Bicalho, E., Teixeira, D., Barbosa, M., and La Scala, N. (2021). Effects of burned and unburned sugarcane harvesting systems on soil CO₂ emission and soil physical, chemical, and microbiological attributes. CATENA, 196, 104903.
Nelissen, V., Ruysschaert, G., Manka’Abusi, D., D’Hose, T., De Beuf, K., Al-Barri, B., Cornelis, W., and Boeckx, P. (2015). Impact of a woody biochar on properties of a sandy loam soil and spring barley during a two year field Experiment. Europ. J. Agronomy, 62, pp. 65–78.
Nikiyuluw, V., Soplanit, R., and Siregar, A. (2018). Efisiensi Pemberian Air dan Kompos Terhadap Mineralisasi NPK pada Tanah Regosol. J. Budidaya Pertanian, 14(2), pp. 105–112.
Prasetyo, A., Listyorini, E., and Utomo, W. (2014). Hubungan sifat fisik tanah, perakaran dan hasil ubi kayu tahun kedua pada Alfisol Jatikerto akibat pemberian pupuk organik dan anorganik. Jurnal Tanah dan Sumberdaya Lahan, 1(1), pp. 27–37.
Razza, F., D’Avino, L., L’Abate, G., and Lazzeri, L. (2018). The role of compost in bio-waste management and circular economy. Designing sustainable technologies, Prod. & Pol., pp. 133–143.
Silva, D., Silva, B., Albuquerque, W., Borges, C., Sousa, D., and Neto, J. (2013). Crop coefficient, water requirements, yield and water use efficiency of sugarcane growth in Brazil. Agricultural Water Management, 128, pp. 102–109.
Siregar, P., Fauzi, and Supriadi. (2017). Pengaruh pemberian beberapa sumber bahan organik dan masa inkubasi terhadap beberapa aspek kimia kesuburan tanah ultisol. Jurnal Agroekoteknologi FP USU, 5(2), pp. 256–264.
Yulianti, T., Hidayah, N., Wijayanti, K., Sujak, S., Sunarto, D., Nurindah, N., Supriadi, S., and Subiyakto. (2023). Sugarcane-trash management for sustaining soil health and decreasing risk of soil-borne diseases, particularly in tropical regions. Applied Ecology And Environmental Research, 21(3), pp. 1837–1854.
Yusara, A., Handoko, and Budianto, B. (2019). Analisis kebutuhan air tanaman tebu berdasarkan model simulasi tanaman (studi kasus: Kabupaten Kediri, Jawa Timur). Agromet, 33(1), pp. 30–40.
Zemánek, P. (2011). Evaluation of compost influence on soil water retention. Acta Universitatis Agriculturae et Silviculturae Mendelianae Brunensis, 59, pp. 227–232.
DOI: https://doi.org/10.22146/ipas.85576
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