A Comprehensive Review on the Recycling of Carbon Fibre–Reinforced Polymer Composite: Recovery Techniques, Material Performance, and Sustainability

Article Sidebar

PDF

Section

Review Article

Issue

Vol. 2 No. 1 (2026): In Progress

How to Cite

Temesgen, A. G., & Cebulla, H. (2026). A Comprehensive Review on the Recycling of Carbon Fibre–Reinforced Polymer Composite: Recovery Techniques, Material Performance, and Sustainability. Global Waste Valorization, 2(1), 1-22. https://doi.org/10.65773/gwv.2.1.98

Main Article Content

Authors

Alhayat Getu Temesgen*
Chenmitz University of Technology, Chemnitz, Germany , Wollo University, Kombolcha Institute of Technology, Kombolcha, Ethiopia
Holger Cebulla
Chenmitz University of Technology, Chemnitz, Germany

Abstract

Carbon fiber–reinforced polymer (CFRP) composites are increasingly used in the aerospace, automotive, wind energy, and construction sectors due to their superior mechanical properties, lightweight nature, and corrosion resistance. However, the rapid growth in CFRP applications has resulted in significant volumes of manufacturing scrap and end-of-life composite waste, posing environmental and economic challenges⁠. Conventional disposal methods such as landfilling and incineration are unsustainable and⁠ increasingly restricted by environmental⁠ regulations. Consequently, recycling of CFRP waste has become a critical research and industrial focus. This review presents a comprehensive overview of current recycling technologies for carbon⁠ fiber–reinforced polymer composites, emphasizing fiber recovery techniques, properties of recycled carbon fibers, and sustainability considerations through life cycle analysis⁠ (LCA). Mechanical, thermal, and chemical recycling routes are discussed in detail, along with their advantages, limitations, and technological maturity. The influence of recycling processes on fiber morphology, surface chemistry, and mechanical performance is analyzed. Furthermore, environmental impacts, energy consumption, and economic feasibility of different recycling pathways are compared. Key challenges, industrial barriers, and future research directions toward circular and sustainable CFRP utilization are also highlighted.

Keywords:
carbon fiber reinforced polymers, recycling, fibre recovery, pyrolysis, solvolysis, life-cycle assessment, sustainability, circular economy

Article Details

References

[1]Kaufmann, J., 2015. New materials for sports equipment made of anisotropic fiber-reinforced plastics with stiffness related coupling effect. Procedia engineering, 112, pp.140-145.

[2]Mallick PK. Fiber-Reinforced Composites: Materials, Manufacturing, and Design. 3rd ed. Boca Raton: CRC Press; 2007.

[3]Marsh G. Airbus A350 XWB update. Reinforced Plastics. 2010;54(6):20-24.

[4]Jacob A. Carbon fibre and cars – 2013 in review. Reinforced Plastics. 2014;58(1):18-19.

[5]Kaufmann, J., Rabe, H., Siebert, N., Wolf, P., Cebulla, H. and Odenwald, S., 2016. Smart carbon fiber bicycle seat post with light and sensor integration. Procedia Engineering, 147, pp.562-567.

[6]Brøndsted P, Lilholt H, Lystrup A. Composite materials for wind power turbine blades. Annual Review of Materials Research. 2005;35:505-538.

[7]Holmes M. Global carbon fibre market remains on upward trend. Reinforced Plastics. 2014;58(6):38-45.

[8]Red C. Wind turbine blades: Big and getting bigger. Composites World. 2018;4(2):27-33.

[9]Pickering SJ. Recycling technologies for thermoset composite materials—current status. Composites Part A. 2006;37(8):1206-1215.

[10]Oliveux G, Dandy LO, Leeke GA. Current status of recycling of fibre reinforced polymers. Progress in Materials Science. 2015;72:61-99.

[11]Liu P, Barlow CY. Wind turbine blade waste in 2050. Waste Management. 2017;62:229-240.

[12]Reinhardt, M., Kaufmann, J., Kausch, M. and Kroll, L., 2013. PLA-viscose-composites with continuous fibre reinforcement for structural applications. Procedia Materials Science, 2, pp.137-143.

[13]Schmidt J., Klingenhöfer M., Kaufmann J., Cebulla H. and Kroll L. Characterization of the interlaminar fracture toughness of unidirectional thermoplastic composites. Technologies for Lightweight Structures (TLS), , 2021. 5(1), pp.69-77.

[14]Yang Y, Boom R, Irion B, van Heerden DJ, Kuiper P, de Wit H. Recycling of composite materials. Chemical Engineering and Processing. 2012;51:53-68.

[15]Naqvi SR, Prabhakara HM, Bramer EA, Dierkes W, Akkerman R, Brem G. A critical review on recycling of end-of-life carbon fibre composites. Resources, Conservation and Recycling. 2018;136:118-129.

[16]Ribeiro I., Kaufmann J. Schmidt A., Peças P., Henriques E. and Götze U. Fostering selection of sustainable manufacturing technologies–a case study involving product design, supply chain and life cycle performance. Journal of Cleaner Production, 2016; 112, pp.3306-3319.

[17]Song YS, Youn JR, Gutowski TG. Life cycle energy analysis of fiber-reinforced composites. Composites Part A. 2009;40(8):1257-1265.

[18]Karuppannan Gopalraj S, Kärki T. A review on the recycling of waste carbon fibre composites. SN Applied Sciences. 2020;2:433.

[19]European Commission. Directive 2008/98/EC on waste. Official Journal of the European Union. 2008;L312:3-30.

[20]US EPA. Resource Conservation and Recovery Act Overview. Washington DC: EPA; 2019.

[21]Zhang J, Chevali VS, Wang H, Wang CH. Current status of carbon fibre recycling. Composites Part B. 2020;193:108053.

[22]Holmes M. Carbon fibre reinforced plastics market continues growth. Reinforced Plastics. 2013;57(6):24-29.

[23]Meng F, Olivetti EA, Zhao Y, Chang JC, Pickering SJ, McKechnie J. Comparing life cycle energy of carbon fiber recycling technologies. ACS Sustainable Chemistry & Engineering. 2018;6(8):9854-9865.

[24]Kaufmann, J., Kroll, L. and Odenwald, S., 2010. Application-specific design of sports equipment from anisotropic fiber-reinforced plastics with stiffness related coupling effect. Procedia Engineering, 2(2), pp.2569-2574.

[25]Morgan P. Carbon Fibers and Their Composites. Boca Raton: CRC Press; 2005.

[26]Fitzer E. Pan-based carbon fibers—present state and trend. Carbon. 1989;27(5):621-645.

[27]Toray Industries. Technical data sheet: Torayca carbon fiber. 2023.

[28]Guigon M, Oberlin A, Desarmot G. Microtexture and structure of PAN-base carbon fibres. Fibre Science and Technology. 1984;20(1):55-72.

[29]Ellis B. Chemistry and Technology of Epoxy Resins. London: Blackie Academic; 1993.

[30]May CA. Epoxy Resins: Chemistry and Technology. 2nd ed. Marcel Dekker; 1988.

[31]Pascault JP, Sautereau H, Verdu J, Williams RJJ. Thermosetting Polymers. Marcel Dekker; 2002.

[32]Biron M. Thermoplastics and Thermoplastic Composites. 2nd ed. Elsevier; 2013.

[33]Drzal LT. The interphase in epoxy composites. Advances in Polymer Science. 1986;75:1-32.

[34]Jones C. The chemistry of carbon fibre surfaces and interfacial phenomena. Composites Science and Technology. 1991;42(4):275-298.

[35]Rybicka J, Tiwari A, Leeke GA. Technology readiness level assessment of composites recycling. Journal of Cleaner Production. 2016;112:1001-1012.

[36]Krauklis AE, Karl CW, Gagani AI, Jørgensen JK. Composite material recycling technology. Journal of Composites Science. 2021;5(1):28.

[37]Howarth J, Mareddy SSR, Mativenga PT. Energy intensity of mechanical recycling. Journal of Cleaner Production. 2014;81:46-50.

[38]Shuaib NA, Mativenga PT. Energy demand in mechanical recycling of composites. Journal of Cleaner Production. 2016;120:198-206.

[39]Pickering SJ, Kelly RM, Kennerley JR, Rudd CD, Fenwick NJ. A fluidised-bed process for recovery of glass fibres. Composites Science and Technology. 2000;60(4):509-523.

[40]Palmer J, Ghita OR, Savage L, Evans KE. Successful closed-loop recycling of thermoset composites. Composites Part A. 2009;40(4):490-498.

[41]Oliveux G, Dandy LO, Leeke GA. Degradation of a model epoxy resin by solvolysis routes. Polymer Degradation and Stability. 2015;118:96-103.

[42]Piñero-Hernanz R, Dodds C, Hyde J, García-Serna J, Poliakoff M, Lester E, et al. Chemical recycling of carbon fibre reinforced composites in nearcritical and supercritical water. Composites Part A. 2008;39(3):454-461.

[43]Liu Y, Meng L, Huang Y, Du J. Recycling of carbon/epoxy composites. Journal of Applied Polymer Science. 2004;94(5):1912-1916.

[44]Okajima I, Hiramatsu M, Shimamura Y, Awaya T, Sako T. Chemical recycling of carbon fiber reinforced plastic using supercritical methanol. Journal of Supercritical Fluids. 2014;91:68-76.

[45]Yan H, Lu CX, Jing DQ, Chang CW, Liu BS, Zhang X. Chemical degradation of amine-cured DGEBA epoxy resin in supercritical 1-propanol. Journal of Applied Polymer Science. 2015;132(12):41686.

[46]Das M, Chacko R, Varughese S. An efficient method of recycling of CFRP waste using peracetic acid. ACS Sustainable Chemistry & Engineering. 2018;6(2):1564-1571.

[47]Morin C, Loppinet-Serani A, Cansell F, Aymonier C. Near- and supercritical solvolysis of carbon fibre reinforced polymers for recycling carbon fibers. Journal of Supercritical Fluids. 2012;66:232-240.

[48]Wang Y, Cui X, Ge H, Yang Y, Wang Y, Zhang C, et al. Chemical recycling of carbon fiber reinforced epoxy resin composites via selective cleavage of the carbon–nitrogen bond. ACS Sustainable Chemistry & Engineering. 2015;3(12):3332-3337.

[49]Keith MJ, Leeke GA, Lester E. Supercritical carbon dioxide extraction of hexabromocyclododecane from polymeric materials. Environmental Science & Technology. 2010;44(12):4570-4575.

[50]Kaufmann J., Temesgen A.G., and Cebulla H. A comprehensive review on natural fiber reinforced hybrid composites processing techniques, material properties and emerging applications. Discover Materials, 2025.5(1), p.227.

[51]Vo Dong PA, Azzaro-Pantel C, Cadene AL. Economic and environmental assessment of recovery pathways for CFRP waste. Resources, Conservation and Recycling. 2018;133:63-75.

[52]Khalil YF. Comparative environmental and human health evaluations of recycling technologies. Waste Management. 2018;76:767-778.

[53]Wong KH, Pickering SJ, Rudd CD. Recycled carbon fibre reinforced polymer composite for EMI shielding. Composites Part A. 2010;41(6):693-702.

[54]Akonda MH, Lawrence CA, Weager BM. Recycled carbon fibre-reinforced polypropylene composites. Composites Part A. 2012;43(1):79-86.

[55]Jiang G, Pickering SJ, Walker GS, Wong KH, Rudd CD. Surface characterisation of carbon fibre recycled using fluidised bed. Applied Surface Science. 2008;254(9):2588-2593.

[56]Yuyan L, Guohua S, Linghui D. A chemical degradation process for the recycling of epoxy/carbon fiber composites. Composites Science and Technology. 2009;69(2):264-270.

[57]Turner TA, Pickering SJ, Warrior NA. Development of recycled carbon fibre moulding compounds. Composites Part B. 2011;42(3):517-525.

[58]Yip HLH, Pickering SJ, Rudd CD. Characterisation of carbon fibres recycled from scrap composites using fluidised bed process. Plastics, Rubber and Composites. 2002;31(6):278-282.

[59]Mativenga PT, Shuaib NA, Howarth J, Pestalozzi F, Woidasky J. High voltage fragmentation and mechanical recycling. CIRP Annals. 2016;65(1):45-48.

[60]Asmatulu E, Twomey J, Overcash M. Recycling of fiber-reinforced composites and direct structural composite recycling concept. Journal of Composite Materials. 2014;48(5):593-608.

[61]Ribeiro MCS, Fiúza A, Ferreira A, Dinis MDL, Meira Castro AC. Recycling approach towards sustainability of composite materials. Recycling. 2016;1(1):178-193.

[62]La Rosa AD, Recca G, Summerscales J, Latteri A, Cozzo G, Cicala G. Bio-based versus traditional polymer composites. Journal of Cleaner Production. 2014;74:135-144.

[63]Mastali M, Dalvand A, Sattarifard AR. The impact resistance and mechanical properties of reinforced self-compacting concrete with recycled glass fibre. Journal of Cleaner Production. 2016;124:312-324.

[64]Sauer M. Composites Market Report 2019. AVK–Industrievereinigung; 2019.

[65]ELG Carbon Fibre Ltd. Technical documentation. 2024.

[66]Ribeiro, I., Kaufmann, J., Schmidt, A., Peças, P., Henriques, E. and Götze, U., 2016. Fostering selection of sustainable manufacturing technologies–a case study involving product design, supply chain and life cycle performance. Journal of Cleaner Production, 112, pp.3306-3319.

[67]Meng F, McKechnie J, Turner TA, Pickering SJ. Energy and environmental assessment of fluidised bed recycled carbon fibres. Composites Part A. 2017;100:206-214.

[68]Shuaib NA, Mativenga PT. Carbon footprint analysis of fibre reinforced composite recycling. Procedia Manufacturing. 2017;7:183-190.

[69]Metzner C., Gessler A., Kaufmann J. and Kroll L. Functionalized braids as potential solution for high performance CFRP structures. In 2nd International MERGE Technologies Conference: IMTC, 2015. (pp. 37-44).

[70]Ribeiro I., Kaufmann J., Götze U., Peças P. and Henriques, E. Fibre reinforced polymers in the sports industry–Life Cycle Engineering methodology applied to a snowboard using anisotropic layer design. International journal of sustainable engineering, 2019.12(3), pp.201-211.

[71]Carvalho H., Raposo A., Ribeiro I., Kaufmann J., Götze U., Peças P. and Henriques, E. Application of Life Cycle Engineering approach to assess the pertinence of using natural fibers in composites–the rocker case study. Procedia CIRP, 2016.48, pp.364-369.

[72]Götze U., Hertel A., Schmidt A., Päßler E. and Kaufmann, J. Integrated framework for life cycle-oriented evaluation of product and process technologies: conceptual design and case study. In Technology and manufacturing process selection: the product life cycle perspective (pp. 193-215). 2013.London: Springer London.

[73]Götze U., Peças P., Salman H.M., Kaufmann J. and SchmidtA. Risk-sensitive life cycle assessment of green composites for automotive applications. In Green Composites for Automotive Applications , 2019. (pp. 219-251). Woodhead Publishing.

[74]Denissen W, Winne JM, Du Prez FE. Vitrimers: permanent organic networks with glass-like fluidity. Chemical Science. 2016;7(1):30-38.

[75]Knight C. The circular economy and the future of composites. Reinforced Plastics. 2019;63(4):194-198.

[76]Beauson J, Brøndsted P. Wind turbine blades: An end of life perspective. In: MARE-WINT. Springer; 2016. p. 421-432.

[77]Jensen JP, Skelton K. Wind turbine blade recycling: Experiences and challenges. Renewable and Sustainable Energy Reviews. 2018;97:165-176.

[78]Job S. Recycling glass fibre reinforced composites – history and progress. Reinforced Plastics. 2013;57(5):19-23.

[79]Liu P, Meng F, Barlow CY. Wind turbine blade end-of-life options: An eco-audit comparison. Journal of Cleaner Production. 2019;212:1268-1281.

[80]Rani M, Choudhary P, Krishnan V, Zafar S. A review on recycling methods for carbon fiber composites. Composites Part B. 2021;215:108768.

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.