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All issues Volume 679 (2025) E3S Web Conf., 679 (2025) 01028 References
Open Access
Issue
E3S Web Conf.
Volume 679, 2025
The 6th Research, Invention, and Innovation Congress (RI2C 2025)
Article Number 01028
Number of page(s) 7
DOI https://doi.org/10.1051/e3sconf/202567901028
Published online 18 December 2025
  1. A. M. Villamagna, B. R. Murphy, Ecological and socio-economic impacts of invasive water hyacinth (Eichhornia crassipes): a review. Freshwater Biology, 55, 282–298 (2010) [Google Scholar]
  2. S. Rezania, M. Ponraj, A. Talaiekhozani, Shaza E. Mohamad, M. F. M. Din, S. Md Taib, F. Sabbagh, F. Md Sairan, Perspectives of phytoremediation using water hyacinth for removal of heavy metals, organic and inorganic pollutants in wastewater. Journal of Environmental Management, 163, 125–133 (2015) [Google Scholar]
  3. P. P. D. Omo; V. Spena; S. L. Froscia, Assessment of a Mechanical Pretreatment to Enhance Biogas Production from the Noxious Weed Eichhornia Crassipes on Industrial Scale. in Proceedings of 5th International Symposium on Environment-Friendly Energies and Applications (EFEA), September September 24-26 (2018) [Google Scholar]
  4. S. Pandey, N. Singh, A. K. Nirala, A. Gir, Dynamics of Water Weed Eichhornia Crassipes: A Review. IJRASET. 3 (2015) [Google Scholar]
  5. G. K. Gaurav, T. Mehmood, L. Cheng, J. J. Klemeš, D. K. Shrivastava, Water hyacinth as a biomass: A review. Journal of Cleaner Production, 277, 122214 (2020) [Google Scholar]
  6. D. Jose, K. Rattanaporn, N. Kittiborwornkul, A. A. Adediran, and M. Sriariyanun, Biorefining Processes for Valorization of Lignocellulosic Biomass for Sustainable Production of Value-Added Products (CRC Press, Boca Raton, London, New York, 2023) [Google Scholar]
  7. H. El-gendi, E. M. El-Fakharany, M. H El-Sayed, D.A. Alenazi, R. Jame, N. Alkhathami, A. S. Khera, M. Abdelaziz, A comprehensive overview of lignocellulosic biomass exploiting for sustainable bioethanol production: recent advances and emerging challenges towards commercial implementation. Egypt. J. Chem. 67, 2053–2072 (2024) [Google Scholar]
  8. O. M. Perrone, M. M. de S. Moretti, S. E. Bordignon, J. de C. Pereira, R. da Silva, E. Gomes, M. Boscolo, Improving cellulosic ethanol production using ozonolysis and acid as a sugarcane biomass pretreatment in mild conditions. BioResources. 13, 100628 (2021) [Google Scholar]
  9. T. Ruan, R. Zeng, X. Y. Yin, S. Zhang, Z.-H. Yang, Water Hyacinth (Eichhornia crassipes) Biomass as a Biofuel Feedstock by Enzymatic Hydrolysis. BioResources. 11, 2372–2380 (2016) [Google Scholar]
  10. B. K. Show, G. Shivakumaran, A. Koley, A. Ghosh, S. Chaudhury, A. K. Hazra, S. Balachandran, Effect of thermal and NaOH pretreatment on water hyacinth to enhance the biogas production. Environmental Science and Pollution Research, 30, 120984–120993 (2023) [Google Scholar]
  11. R. D. Umai, S. Jacob, V. Kumar, Deep Eutectic Solvent Pretreatment of Water Hyacinth for Improved Holocellulosic Saccharification and Fermentative Co-Production of Xylitol and Lipids Using Rhodosporidium toruloides NCIM 3547. Fermentation, 8, 591 (2022) [Google Scholar]
  12. Y.-Q. Sun, Y. Yuan, K.-X. Dai, Z.-L. Xiu, The pretreatment of the sustainable biomass feedstock of Pennisetum giganteum for biorefinery using deep eutectic solvents. Bioresource Technology, 384, 129289 (2023) [Google Scholar]
  13. M. Sulaiman, H. Mahmood, H. M. Khan, T. Iqbal, N. U. Khan, M. M. Abbas, M. N.-E.-Alam, M. E. M. Soudagar, Cellulosic rich biomass production with optimized process parameters by using glycerol pretreatment for biofuels applications. Energy Nexus, 14, 100298 (2024) [Google Scholar]
  14. K. Narayanan, P. Venkatachalam, E. J. Panakkal, P. Tantayotai, A. Tandhanskul, R. Selvasembian, S. Chuetor, M. Sriariyanun, Exploring Ternary Deep Eutectic Solvent Pretreatment in a One-Pot Process with Napier Grass for Bioethanol Production. BioEnergy Research, 17, 2213–2225 (2024) [Google Scholar]
  15. S. L. Sunar, R. K. Oruganti, D. Bhattacharyya, D. Shee and T. K. Panda, Pretreatment of sugarcane bagasse using ionic liquid for enhanced enzymatic saccharification and lignin recovery: process optimization by response surface methodology. Cellulose, 31, 2151–2173 (2024) [Google Scholar]
  16. S. Areeya, M. P. Gundupalli, B. Dharmalingam, B. Paramasivam, P. Tantayotai, P. Yasurin, E. J. Panakkal, Process Optimization of Deep Eutectic Solvent Pretreatment of Coffee Husk Biomass. E3S Web of Conferences, 428, 01010 (2023) [Google Scholar]
  17. D. Pradhan, S. Jaiswal, B. K. Tiwari, A. K. Jaiswal, Nanocellulose separation from barley straw via ultrasound-assisted choline chloride – Formic acid deep eutectic solvent pretreatment and high-intensity ultrasonication. Ultrasonics Sonochemistry, 110, 107048 (2024) [Google Scholar]
  18. B. Timoteo-Cruz, R. M. Gómez-Espinosa, R. Sánchez-Orozco, J. J. García-Sánchez, F. Ureña-Núñez and G. Roa-Morales, Pretreatment of Typha latifolia biomass with imidazolium ionic liquid as a strategy for sugar production. Biomass Conversion and Biorefinery, 14, 4591–4604 (2024) [Google Scholar]
  19. M. Pawłowska, M. Zdeb and M. Nieścioruk, Efficiency of Chemical Pretreatment of Sugar Beet Pulp Biomass Intended to Energy Production via Biological Processes, Energies, 16, 574 (2023) [Google Scholar]
  20. R. P. Martins, A. A. Schmatz, L. A. de Freita, M J. R. Mutton, M. Brienzo, Solubilization of hemicellulose and fermentable sugars from bagasse, stalks, and leaves of sweet sorghum. Industrial Crops and Products, 170, 113813 (2021) [Google Scholar]
  21. M. Ivanović, D. Grujić, J. Cerar, M. I. Razboršek, L. Topalić-Trivunović, A. Savić, D. Kočar, Mitja Kolar, Extraction of Bioactive Metabolites from Achillea millefolium L. with Choline Chloride Based Natural Deep Eutectic Solvents: A Study of the Antioxidant and Antimicrobial Activity. Antioxidants, 11, 724 (2022) [CrossRef] [PubMed] [Google Scholar]
  22. O. Govindaraj, G. N. Olaganathan, R. ASM, S. Uthandi, An eco-friendly EnZolv pretreatment optimization in banana fiber biomass using response surface methodology (RSM) and its structural characterization. Biomass Conversion and Biorefinery, 14, 1329–1342 (2023) [Google Scholar]
  23. P. Kahar, Synergistic Effects of Pretreatment Process on Enzymatic Digestion of Rice Straw for Efficient Ethanol Fermentation. Environmental Biotechnology New Approaches and Prospective Applications, 65–87 (2013) [Google Scholar]
  24. G.L. Miller, Anal. Chem. 14, 426–428 (1959) [Google Scholar]
  25. E.K. Tetteh, S. Rathilal, Response Surface Optimization of Biophotocatalytic Degradation of Industrial Wastewater for Bioenergy Recovery, 9, 3 (2022) [Google Scholar]
  26. R.H. Jadhav and A. Dey, Pre-Treatment and Characterization of Water Hyacinth Biomass (WHB) for Enhanced Xylose Production Using Dilute Alkali Treatment Method, Water, 17, 301 (2025) [Google Scholar]
  27. J.L. Morales-Martínez, M.G. Aguilar-Uscanga, E. Bolaños-Reynoso, L. López-Zamora, Optimization of chemical pretreatments using response surface methodology for second-generation ethanol production from coffee husk waste. BioEnergy Research, 14, 815–827 (2021) [CrossRef] [Google Scholar]
  28. Z. Yao, G. Chong, H. Guo, Deep Eutectic Solvent Pretreatment and Green Separation of Lignocellulose. Appl. Sci. 14, 7662 (2024) [Google Scholar]
  29. K. C. Patil, R. H. Patil, Qualitative characterization of pretreated fruit waste to produce an effective fertilizer by using FTIR. 2022 IJCRT. 10, 12 (2022) [Google Scholar]
  30. J. E. H. Rodríguez, D. E. Rincón, D. F. H. Rojas, I. G. C. Orjuela, L. M. Socolovsky, D. G. E. Rondón, C. L. L. Calderón, Effects of Hydrolysis and Bleaching Conditions on the Efficiency of Cellulose Microribbons Extraction from Coffee Parchment Through a Design of Experiments, Cellulose (2022) [Google Scholar]
  31. W. Wang, C. Wang, Zahoor, X. Chen, Q. Yu, Z. Wang, X. Zhuang, Z. Yuan, Effect of a Nonionic Surfactant on Enzymatic Hydrolysis of Lignocellulose Based on Lignocellulosic Features and Enzyme Adsorption, ACS Omega. 5 15812–15820 (2020) [Google Scholar]
  32. R. Vârban, I. Crişan, D. Vârban, A. Ona, L. Olar, A. Stoie, R. Ştefan, Comparative FTIR Prospecting for Cellulose in Stems of Some Fiber Plants: Flax, Velvet Leaf, Hemp and Jute. Appl. Sci. 11, 8570 (2021) [Google Scholar]
  33. J. Kalembkiewicz, D. Galas, E. Sitarz-Palczak, The Physicochemical Properties and Composition of Biomass Ash and Evaluating Directions of its Applications, Pol. J. Environ. Stud. 27, 6 (2018) [Google Scholar]
  34. A. Mudzakir, A. B. D. Nandiyanto, E. Heraldy, J. Efendi, K. M. Rizky, M. Widyaningsih, L.S. Anggiat, Dissolution Study of Lignin from Coconut Fiber as Lignocellulosic Biomass Using Eutectic Based Ionic Liquids, in Proceedings of the 9th Mathematics, Science, and Computer Science Education International Seminar (MSCEIS 2023) [Google Scholar]
  35. Z. Zhu, R. Simister, S. Bird, S. J. McQueen-Mason, L. D. Gomez, D. J. Macquarrie, Microwave assisted acid and alkali pretreatment of Miscanthus biomass for biorefineries, AIMS Bioengineering 2, 449–468 (2015) [Google Scholar]
  36. S. Machmudah, Wahyudiono, P. N. Trisanti, H. Setyawan, S. Madhania, K. Sambodho, S. Winardi, T. Adschiri, M. Goto, Hydrothermal alkaline treatment of lignocellulosic biomass for microcrystalline cellulose generation at subcritical water, South African Journal of Chemical Engineering. 51, 45–56 (2025) [Google Scholar]

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