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Sugarcane Bagasse: Challenges and Opportunities for Waste Recycling

Author

Listed:
  • Carlos T. Hiranobe

    (School of Engineering and Science (FEC—UNESP), São Paulo State University, Rosana 19274-000, SP, Brazil)

  • Andressa S. Gomes

    (School of Technology and Science (FCT—UNESP), São Paulo State University, Presidente Prudente 19060-900, SP, Brazil)

  • Fábio F. G. Paiva

    (Pró-Rectory of Research and Graduate Studies, Graduate Program in Environment and Regional Development, University of Western São Paulo (UNOESTE), Presidente Prudente 19067-175, SP, Brazil)

  • Gabrieli R. Tolosa

    (School of Technology and Science (FCT—UNESP), São Paulo State University, Presidente Prudente 19060-900, SP, Brazil)

  • Leonardo L. Paim

    (School of Engineering and Science (FEC—UNESP), São Paulo State University, Rosana 19274-000, SP, Brazil)

  • Guilherme Dognani

    (School of Technology and Science (FCT—UNESP), São Paulo State University, Presidente Prudente 19060-900, SP, Brazil)

  • Guilherme P. Cardim

    (School of Engineering and Science (FEC—UNESP), São Paulo State University, Rosana 19274-000, SP, Brazil)

  • Henrique P. Cardim

    (School of Engineering and Science (FEC—UNESP), São Paulo State University, Rosana 19274-000, SP, Brazil)

  • Renivaldo J. dos Santos

    (School of Engineering and Science (FEC—UNESP), São Paulo State University, Rosana 19274-000, SP, Brazil)

  • Flávio C. Cabrera

    (School of Engineering and Science (FEC—UNESP), São Paulo State University, Rosana 19274-000, SP, Brazil)

Abstract

Sugarcane has primarily been used for sugar and ethanol production. It creates large quantities of residual lignocellulosic biomass such as sugarcane bagasse, leaves, tops, and vinasse. Biomass is a sustainable prospect for biorefineries aiming to optimize production processes. We detail recent research developments in recycling sugarcane, including energy generation and pyrolysis to obtain biofuels, for example. To produce biochar, the energy cost of operating at high temperatures and large-scale production remain as obstacles. The energy generation prospects can be enhanced by pellet production; however, it requires an improvement in quality control for long-term storage or long-distance transportation. In civil construction, the materials still need to prove their long-term efficiency and reliability. Related to adsorbent materials, the use of sugarcane bagasse has the advantage of being low-cost and environmentally friendly. Nevertheless, the extraction, functionalization, and modification of cellulose fibers, to improve their adsorption properties or even mode of operation, still challenges. The synthesis of nanostructures is still lacking high yields and the ability to scale up. Finally, controlling dispersion and orientation and avoiding fiber agglomeration could improve the mechanical response of composites using sugarcane bagasse. The different possibilities for using sugarcane and its residues reinforce the importance of this material for the industry and the global economy. Thus, the present work addresses current challenges and perspectives of different industrial processes involving sugarcane aiming to support future research on waste-derived subjects.

Suggested Citation

  • Carlos T. Hiranobe & Andressa S. Gomes & Fábio F. G. Paiva & Gabrieli R. Tolosa & Leonardo L. Paim & Guilherme Dognani & Guilherme P. Cardim & Henrique P. Cardim & Renivaldo J. dos Santos & Flávio C. , 2024. "Sugarcane Bagasse: Challenges and Opportunities for Waste Recycling," Clean Technol., MDPI, vol. 6(2), pages 1-38, June.
    • Handle: RePEc:gam:jcltec:v:6:y:2024:i:2:p:35-699:d:1407729
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    References listed on IDEAS

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    1. Gautam, Neha & Chaurasia, Ashish, 2020. "Study on kinetics and bio-oil production from rice husk, rice straw, bamboo, sugarcane bagasse and neem bark in a fixed-bed pyrolysis process," Energy, Elsevier, vol. 190(C).
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    3. Prajapati, Bhanu Pratap & Jana, Uttam Kumar & Suryawanshi, Rahul Kumar & Kango, Naveen, 2020. "Sugarcane bagasse saccharification using Aspergillus tubingensis enzymatic cocktail for 2G bio-ethanol production," Renewable Energy, Elsevier, vol. 152(C), pages 653-663.
    4. Van Meerbeek, Koenraad & Muys, Bart & Hermy, Martin, 2019. "Lignocellulosic biomass for bioenergy beyond intensive cropland and forests," Renewable and Sustainable Energy Reviews, Elsevier, vol. 102(C), pages 139-149.
    5. Al Arni, Saleh, 2018. "Comparison of slow and fast pyrolysis for converting biomass into fuel," Renewable Energy, Elsevier, vol. 124(C), pages 197-201.
    6. Ingle, Avinash P. & Philippini, Rafael R. & Silvério da Silva, Silvio, 2020. "Pretreatment of sugarcane bagasse using two different acid-functionalized magnetic nanoparticles: A novel approach for high sugar recovery," Renewable Energy, Elsevier, vol. 150(C), pages 957-964.
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    1. Dasith Wijesekara & Lasitha Kularathna & Pawani Abesundara & Udayangani Lankathilaka & Imesha Muhandiram & Prasad Amarasinghe & Shakya Abesinghe & Chanaka Galpaya & Kaveenga Koswattage, 2025. "Comparative Energy and Environmental Analysis of Combined Cycle CHP Combustion Operations via Simulation for Biomass and Industrial Materials Derived from Waste," Energies, MDPI, vol. 18(12), pages 1-21, June.

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