Contributions of bio-based materials towards achieving carbon neutrality and ecological civilization: a life cycle assessment perspective

Zhenlu Wang , Jiamin Wu , Liping Cai , Changlei Xia

Energy, Ecology and Environment ›› : 1 -15.

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Energy, Ecology and Environment ›› :1 -15. DOI: 10.1007/s40974-026-00408-9
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Contributions of bio-based materials towards achieving carbon neutrality and ecological civilization: a life cycle assessment perspective
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Bio-based materials / Carbon neutrality / Life Cycle Assessment (LCA) / Environmental impact / Renewable resources

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Zhenlu Wang, Jiamin Wu, Liping Cai, Changlei Xia. Contributions of bio-based materials towards achieving carbon neutrality and ecological civilization: a life cycle assessment perspective. Energy, Ecology and Environment 1-15 DOI:10.1007/s40974-026-00408-9

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Abadega AF, Abawaji IA. Land restoration and socio-economic contribution of bamboo in Ethiopia. J Degraded Min Lands Manage. 2021, 8: 2617-2621.

[2]

Abdelrhman HA, Paridah MT, Almaleeh TA, Abdan K. Modelling carbon footprint, emission, and sequestration of kenaf cultivation and fiber processing and utilization into automotive components. Bio Resour. 2023, 18: 4558-4566.

[3]

Akhil UV, Radhika N, Saleh B, Krishna SA, Noble N, Rajeshkumar L. A comprehensive review on plant-based natural fiber reinforced polymer composites: fabrication, properties, and applications. Polym Compos. 2023, 44: 2598-2633.

[4]

Alba-Reyes Y, Sánchez-Valle Y, Ramos-Aquino RG, Barrera EL, Jiménez J. Lifecycle assessment of Nicotiana tabacum L.: sustainability of seedling alternatives. Energy Ecol Environ. 2025, 10: 79-93.

[5]

Alemu D, Tafesse M, Mondal AK. Mycelium-based composite: thefuture sustainable biomaterial. Int J Biomater. 2022, 2022: 8401528.

[6]

Bekhta P, Sedliačik J, Jones D. Effect of short-term thermomechanical densification of wood veneers on the properties of birch plywood. Eur J Wood Wood Prod. 2018, 76549-562.

[7]

Cabeza LF, Rincón L, Vilariño V, Pérez G, Castell A. Life cycle assessment (LCA) and life cycle energy analysis (LCEA) of buildings and the building sector: a review. Renew Sustain Energy Rev. 2014, 29: 394-416.

[8]

Chen L-S, Fei B-H, Ma X-X, Lu J-P, Fang C-H. Investigation of bamboo grid packing properties used in cooling tower. Forests. 2018, 9: 762.

[9]

Chen L-S, Fei B-H, Ma X-X, Lu J-P, Fang C-H. Effects of hygrothermal environment in cooling towers on the chemical composition of bamboo grid packing. Forests. 2019, 10274.

[10]

Van Der Cherubini F, Huijbregts M, Kindermann G, Van ZelmR M, Stadler K, Strømman AH. Global spatially explicit CO2 emission metrics for forest bioenergy. Sci Rep. 2016, 620186.

[11]

Choi JY, Nam J, Yuk H, Yun BY, Lee S, Lee JK, Kim S. Proposal of retrofit of historic buildings as cafes in Korea: recycling biomaterials to improve building energy and acoustic performance. Energy Build. 2023, 287112988.

[12]

Ciacci L, Passarini F. Life cycle assessment (LCA) of environmental and energy systems. Energies. 2020, 135892.

[13]

Cucurachi S, Steubing B, Siebler F, Navarre N, Caldeira C, Sala S (2022)Prospective LCA methodology for novel and emerging technologies for bio-based products. the planet bio project, publications office of the european union, luxembourg, JRC129632 https://doi.org/10.2760/167543
[14]

Degen F, Schütte M. Life cycle assessment of the energy consumption and GHG emissions of state-of-the-art automotive battery cell production. J Clean Prod. 2022, 330129798.

[15]

Dunlap J, Schramski JR, Li G, Li K. Identifying uncertainty in the global warming impacts of biomaterials: an analysis of biosuccinic acid. Int J Life Cycle Assess. 2024, 291137-1149.

[16]

de Ferreira SR, Andra Silva F, Lopes Lima PR, Toledo Filho RD. Effect of hornification on the structure, tensile behavior and fiber matrix bond of sisal, jute and curaua fiber cement based composite systems. Constr Build Mater. 2017, 139: 551-561.

[17]

Frischknecht R, Wyss F, Büsser Knöpfel S, Lützkendorf T, Balouktsi M. Cumulative energy demand in LCA: the energy harvested approach. Int J Life Cycle Assess. 2015, 20: 957-969.

[18]

García-Olivares A. Substitutability of electricity and renewable materials for fossil fuels in a post-carbon economy. Energies. 2015, 8: 13308-13343.

[19]

Geng A, Yang H, Chen J, Hong Y. Review of carbon storage function of harvested wood products and the potential of wood substitution in greenhouse gas mitigation. Policy Econ. 2017, 85: 192-200.

[20]

George M, Bressler DC. Comparative evaluation of the environmental impact of chemical methods used to enhance natural fibres for composite applications and glass fibre based composites. J Clean Prod. 2017, 149: 491-501.

[21]

Huan J, Han L. Potential contribution to carbon neutrality strategy from industrial symbiosis: evidence from a local coal-aluminum-electricity-steel industrial system. Sustainability. 2022, 14: 2487.

[22]

ISO (2006a) ISO 14040:2006, Environmental Management – Life Cycle Assessment – Principles and Framework.
[23]

ISO (2006b) ISO 14044: 2006, Environmental management — Life cycle assessment — Requirements and guidelines.
[24]

ISO (2010) ISO 21931-1:2010, Sustainability in building construction. Framework for methods of assessment of the environmental performance of construction works -- Part 1: Buildings.
[25]

ISO (2011) ISO/TS 21929-1: 2011, sustainability in building construction—Sustainability indicators—Part 1: Framework for the development of indicators and a core set of indicators for buildings.
[26]

ISO (2018) ISO 14067:2018, Greenhouse gases — Carbon footprint of products — Requirements and guidelines for quantification.
[27]

ISO (2023) ISO 14068-1:2023 Climate change management — Transition to net zero — Part 1: Carbon neutrality.
[28]

Kudzin MH, Piwowarska D, Festinger N, Chruściel JJ. Risks associated with the presence of polyvinyl chloride in the environment and methods for its disposal and utilization. Materials. 2023.

[29]

Lippiatt BC. Bees 4.0: Building for environmental and economic sustainability. technical manual and user guide. 2007National Institute for Standards and Technology.

[30]

Li Q, Yu X, Liu L, Wang D, Guo Z, Alfarraj O, Tolba A. Influential effect analysis of digital transportation policies on urban economic green transition. Humanit Soc Sci Commun. 2025.

[31]

Liu TQ, Chen L, Yang MY, Sandanayake M, Miao PY, Shi Y, Yap PS. Sustainability considerations of green buildings: a detailed overview on current advancements and future considerations. Sustainability. 2022, 1414393.

[32]

Li YY, Fu QL, Rojas R, Yan M, Lawoko M, Berglund L. Lignin-retaining transparent wood. ChemSusChem. 2017, 103445-3451.

[33]

Li YY, Vasileva E, Sychugov I, Popov S, Berglund L. Optically transparent wood: recent progress, opportunities, and challenges. Adv Opt Mater. 2018, 6. 1800059
[34]

Lohtander T, Herrala R, Laaksonen P, Franssila S, Österberg M. Lightweight lignocellulosic foams for thermal insulation. Cellulose. 2022, 29: 1855-1871.

[35]

Malokar AA, Naktode PL. Study of behavior of locally available bamboo as a sustainable reinforcement for concrete structures. Arch Civil Eng. 2022, 68: 339-352.

[36]

Ma X, Cai L, Chen L, Fei B, Lu J, Xia C, Lam SS. Bamboo grid versus polyvinyl chloride as packing material in cooling tower: energy efficiency and environmental impact assessment. J Environ Manage. 2021, 286. 112190
[37]

McLellan BC, Corder GD, Giurco DP, Ishihara KN. Renewable energy in the minerals industry: a review of global potential. J Clean Prod. 2012, 32: 32-44.

[38]

Mi RY, Chen CJ, Keplinger T, Pei Y, He SM, Liu DP, Li JG, Dai JQ, Hitz E, Yang B, Burgert I, Hu LB. Scalable aesthetic transparent wood for energy efficient buildings. Nat Commun. 2020, 11. 3836
[39]

Muangnoi T, Asvapoositkul W, Wongwises S. An exergy analysis on the performance of a counterflow wet cooling tower. Appl Therm Eng. 2007, 27: 910-917.

[40]

Nuss P, Eckelman MJ. Life cycle assessment of metals: a scientific synthesis. PLoS One. 2014.

[41]

Pignagnoli A, Pignedoli S, Carpana E, Costa C, Dal Prà A. Carbon Footprint of Honey in Different Beekeeping Systems. Sustainability. 2021, 13. 11063
[42]

Pingoud K, Ekholm T, Savolainen I. Global warming potential factors and warming payback time as climate indicators of forest biomass use. Mitig Adapt Strateg Glob Change. 2011, 17: 369-386.

[43]

Rajendran S, Al-Samydai A, Palani G, Trilaksana H, Sathish T, Giri J, Saravanan R, Lalvani JIJ, Nasri F. Replacement of petroleum based products with plant‐based materials, green and sustainable energy—a review. Eng Rep. 2025.

[44]

Ramesh T, Prakash R, Shukla KK. Life cycle energy analysis of buildings: an overview. Energy Build. 2010, 42: 1592-1600.

[45]

Roy P, Defersha F, Rodriguez-Uribe A, Misra M, Mohanty AK. Evaluation of the life cycle of an automotive component produced from biocomposite. J Clean Prod. 2020, 273. 123051
[46]

Rybaczewska-Błażejowska M, Jezierski D. Comparison of ReCiPe 2016, ILCD 2011, CML-IA baseline and IMPACT 2002 + LCIA methods: a case study based on the electricity consumption mix in Europe. Int J Life Cycle Assess. 2024, 29: 1799-1817.

[47]

Sahoo K, Bergman R, Runge T. Life-cycle assessment of redwood lumber products in the US. Int J Life Cycle Assess. 2021, 26: 1702-1720.

[48]

Sathre R, O’Connor J. Meta-analysis of greenhouse gas displacement factors of wood product substitution. Environ Sci Policy. 2010, 13: 104-114.

[49]

Segovia F, Blanchet P, Amor B, Barbuta C, Beauregard R. Life cycle assessment contribution in the product development process: case study of wood aluminum-laminated panel. Sustainability. 2019.

[50]

Sharma A, Saxena A, Sethi M, Shree V, Varun. Life cycle assessment of buildings: A review. Renew Sustain Energy Rev. 2011, 15: 871-875.

[51]

Shi SQ, Cai L, Weng Y, Wang D, Sun Y. Comparative life-cycle assessment of water supply pipes made from bamboo vs. polyvinyl chloride. J Clean Prod. 2019, 240. 118172
[52]

Sinha A, Kutnar A. Carbon footprint versus performance of aluminum, plastic, and wood window frames from cradle to gate. Buildings. 2012, 2: 542-553.

[53]

Srivastava RK, Shetti NP, Reddy KR, Kwon EE, Nadagouda MN, Aminabhavi TM. Biomass utilization and production of biofuels from carbon neutral materials. Environ Pollut. 2021, 276. 116731
[54]

Tan J, Wang R. Research on evaluation and influencing factors of regional ecological efficiency from the perspective of carbon neutrality. J Environ Manage. 2021, 294. 113030
[55]

Thompson RC, Moore CJ, vom Saal FS, Swan SH. Plastics, the environment and human health: current consensus and future trends. Philos Trans R Soc Lond B Biol Sci. 2009, 364: 2153-2166.

[56]

Üçtuğ FG, Vali V, Tok N, Fereidani BM. Gate-to-gate life cycle assessment of petrochemicals production in Türkiye: a case study of acrylonitrile and C4. Energy Ecol Environ. 2025, 10: 94-109.

[57]

Valentová M, Makešová M. Motivations for participation in energy communities: evidence from Czech municipalities and multi-apartment buildings using a mixed-methods approach. Energy Ecol Environ. 2026.

[58]

Van der Lugt P, van den Dobbelsteen AAJF, Janssen JJA. An environmental, economic and practical assessment of bamboo as a building material for supporting structures. Constr Build Mater. 2006, 20: 648-656.

[59]

Väisänen T, Das O, Tomppo L. A review on new bio-based constituents for natural fiber-polymer composites. J Clean Prod. 2017, 149: 582-596.

[60]

Wang X, Yang S, Yang R, Yang Z. Analysis of the spatiotemporal evolution and factors influencing ecological land in Northwest Yunnan from the perspective of leading the construction of a National Ecological Civilization. Diversity. 2023, 15. 1074
[61]

Wiesen K, Wirges M. From cumulated energy demand to cumulated raw material demand: the material footprint as a sum parameter in life cycle assessment. Energy Sustain Soc. 2017, 7. 13
[62]

Wu J, Ye H, Li S, Que Z, Peng Y, Cai L, Xia C. Life cycle assessment of transparent wood in building industry: a sustainable solution for global warming mitigation. Constr Build Mater. 2024, 438. 137303
[63]

Wu Y, Xia C, Cai L, Garcia AC, Shi SQ. Development of natural fiber-reinforced composite with comparable mechanical properties and reduced energy consumption and environmental impacts for replacing automotive glass-fiber sheet molding compound. J Clean Prod. 2018, 184: 92-100.

[64]

Xia C, Shi SQ, Cai L, Hua J. Property enhancement of kenaf fiber composites by means of vacuum-assisted resin transfer molding (VARTM). Holzforschung. 2015, 69: 307-312.

[65]

Xia C, Wu Y, Qiu Y, Cai L, Smith LM, Tu M, Zhao W, Shao D, Mei C, Nie X, Shi SQ. Processing high-performance woody materials by means of vacuum-assisted resin infusion technology. J Clean Prod. 2019, 241. 118340
[66]

Xia Q, Chen C, Li T, He S, Gao J, Wang X, Hu L. Solar-assisted fabrication of large-scale, patternable trans­parent wood. Sci Adv. 2021, 7: eabd7342.

[67]

Ye L, Qi C, Hong J, Ma X. Life cycle assessment of polyvinyl chloride production and its recyclability in China. J Clean Prod. 2017, 1422965-2972.

[68]

Zhou C, Cai L, Chen Z, Li J. Effect of kenaf fiber on mechanical properties of high-strength cement composites. Constr Build Mater. 2020, 263. 121007
[69]

Zhou C, Shi SQ, Chen Z, Cai L, Smith L. Comparative environmental life cycle assessment of fiber reinforced cement panel between kenaf and glass fibers. J Clean Prod. 2018, 200: 196-204.

[70]

Zier M, Stenzel P, Kotzur L, Stolten D. A review of decarbonization options for the glass industry. Energy Conversion and Management: X. 2021, 10. 100083

Funding

Postgraduate Research & Practice Innovation Program of Jiangsu Province(KYCX22_1082)

Ministry of Human Resources and Social Security of the People's Republic of China National Foreign Experts Project(H20250250)

RIGHTS & PERMISSIONS

The Author(s), under exclusive licence to the International Society of Energy and Environmental Science

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