Methane pyrolysis-enabled production of high-value carbon fibres

Tangyuan Li; Canhui Wang; Cliff A. Wood; Kaizhu Zeng; Qi Dong; Matthew Gonzalez; Bodiuzzaman Jony; Sichao Cheng; Xinpeng Zhao; Alexandra H. Brozena; Kishor Gupta; Pedro J. Arias-Monje; Xin Zhang; Keenan J. Mintz; Han Zong; Shen Wang; Xizheng Wang; Hongmei Gu; Dongxia Liu; Ping Liu; Satish Kumar; Chao Wang; Liangbing Hu

doi:10.1038/s41893-026-01815-w

Methane pyrolysis-enabled production of high-value carbon fibres

Tangyuan Li
, Canhui Wang
, Cliff A. Wood
, Kaizhu Zeng
, Qi Dong
, Matthew Gonzalez
, Bodiuzzaman Jony
, Sichao Cheng
, Xinpeng Zhao
, Alexandra H. Brozena
, Kishor Gupta
, Pedro J. Arias-Monje
, Xin Zhang
, Keenan J. Mintz
, Han Zong
, Shen Wang
, Xizheng Wang
, Hongmei Gu
, Dongxia Liu
, Ping Liu

Satish Kumar, Chao Wang, Liangbing Hu

Research output: Contribution to Journal › Research Article › peer-review

Abstract

Carbon fibres (CFs) are indispensable for lightweight structural engineering, yet their widespread adoption is stifled by the high cost and environmental toll of polyacrylonitrile (PAN) precursors. While substituting PAN with low-footprint alternatives such as lignin or carbon black reduces emissions, the resulting fibres typically suffer from mechanical degradation caused by poorly integrated fillers. Here we report an electrified carbon-fibre upgrading strategy that transforms low-cost, carbon-black-loaded PAN precursors into high-performance CFs by incorporating methane (CH₄)-derived carbon. By using a porous, aligned fibril network as a Joule-heating element, we achieve rapid, high-temperature pyrolysis at 1,700 K that drives CH₄ diffusion and densification of the internal microstructure. The resulting upgraded carbon fibres, comprising ~50 wt% CH₄-derived carbon, exhibit a tensile strength of 1.7 GPa and a modulus of 173 GPa. This electrified synthesis simultaneously slashes production costs to ~US$13.52 kg_CF⁻¹ and carbon footprints to ~22.39 kg_CO2 kg_CF⁻¹, offering a commercially viable pathway for high-volume industries such as automotive manufacturing. Our findings establish a circular carbon economy model that converts greenhouse gases into high-value structural materials while yielding hydrogen as a clean coproduct.

Original language	English (US)
Journal	Nature Sustainability
DOIs	https://doi.org/10.1038/s41893-026-01815-w
State	Accepted/In press - 2026
Externally published	Yes

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

All Science Journal Classification (ASJC) codes

Global and Planetary Change
Food Science
Geography, Planning and Development
Ecology
Renewable Energy, Sustainability and the Environment
Urban Studies
Nature and Landscape Conservation
Management, Monitoring, Policy and Law

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10.1038/s41893-026-01815-w

Cite this

Li, T., Wang, C., Wood, C. A., Zeng, K., Dong, Q., Gonzalez, M., Jony, B., Cheng, S., Zhao, X., Brozena, A. H., Gupta, K., Arias-Monje, P. J., Zhang, X., Mintz, K. J., Zong, H., Wang, S., Wang, X., Gu, H., Liu, D., ... Hu, L. (Accepted/In press). Methane pyrolysis-enabled production of high-value carbon fibres. Nature Sustainability. https://doi.org/10.1038/s41893-026-01815-w

@article{89d52bdc344b4087afe1be46fde12b13,

title = "Methane pyrolysis-enabled production of high-value carbon fibres",

abstract = "Carbon fibres (CFs) are indispensable for lightweight structural engineering, yet their widespread adoption is stifled by the high cost and environmental toll of polyacrylonitrile (PAN) precursors. While substituting PAN with low-footprint alternatives such as lignin or carbon black reduces emissions, the resulting fibres typically suffer from mechanical degradation caused by poorly integrated fillers. Here we report an electrified carbon-fibre upgrading strategy that transforms low-cost, carbon-black-loaded PAN precursors into high-performance CFs by incorporating methane (CH4)-derived carbon. By using a porous, aligned fibril network as a Joule-heating element, we achieve rapid, high-temperature pyrolysis at 1,700 K that drives CH4 diffusion and densification of the internal microstructure. The resulting upgraded carbon fibres, comprising \textasciitilde{}50 wt\% CH4-derived carbon, exhibit a tensile strength of 1.7 GPa and a modulus of 173 GPa. This electrified synthesis simultaneously slashes production costs to \textasciitilde{}US\$13.52 kgCF−1 and carbon footprints to \textasciitilde{}22.39 kgCO2 kgCF−1, offering a commercially viable pathway for high-volume industries such as automotive manufacturing. Our findings establish a circular carbon economy model that converts greenhouse gases into high-value structural materials while yielding hydrogen as a clean coproduct.",

author = "Tangyuan Li and Canhui Wang and Wood, \{Cliff A.\} and Kaizhu Zeng and Qi Dong and Matthew Gonzalez and Bodiuzzaman Jony and Sichao Cheng and Xinpeng Zhao and Brozena, \{Alexandra H.\} and Kishor Gupta and Arias-Monje, \{Pedro J.\} and Xin Zhang and Mintz, \{Keenan J.\} and Han Zong and Shen Wang and Xizheng Wang and Hongmei Gu and Dongxia Liu and Ping Liu and Satish Kumar and Chao Wang and Liangbing Hu",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature Limited 2026.",

year = "2026",

doi = "10.1038/s41893-026-01815-w",

language = "English (US)",

journal = "Nature Sustainability",

issn = "2398-9629",

publisher = "Nature Publishing Group",

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TY - JOUR

T1 - Methane pyrolysis-enabled production of high-value carbon fibres

AU - Li, Tangyuan

AU - Wang, Canhui

AU - Wood, Cliff A.

AU - Zeng, Kaizhu

AU - Dong, Qi

AU - Gonzalez, Matthew

AU - Jony, Bodiuzzaman

AU - Cheng, Sichao

AU - Zhao, Xinpeng

AU - Brozena, Alexandra H.

AU - Gupta, Kishor

AU - Arias-Monje, Pedro J.

AU - Zhang, Xin

AU - Mintz, Keenan J.

AU - Zong, Han

AU - Wang, Shen

AU - Wang, Xizheng

AU - Gu, Hongmei

AU - Liu, Dongxia

AU - Liu, Ping

AU - Kumar, Satish

AU - Wang, Chao

AU - Hu, Liangbing

PY - 2026

Y1 - 2026

N2 - Carbon fibres (CFs) are indispensable for lightweight structural engineering, yet their widespread adoption is stifled by the high cost and environmental toll of polyacrylonitrile (PAN) precursors. While substituting PAN with low-footprint alternatives such as lignin or carbon black reduces emissions, the resulting fibres typically suffer from mechanical degradation caused by poorly integrated fillers. Here we report an electrified carbon-fibre upgrading strategy that transforms low-cost, carbon-black-loaded PAN precursors into high-performance CFs by incorporating methane (CH4)-derived carbon. By using a porous, aligned fibril network as a Joule-heating element, we achieve rapid, high-temperature pyrolysis at 1,700 K that drives CH4 diffusion and densification of the internal microstructure. The resulting upgraded carbon fibres, comprising ~50 wt% CH4-derived carbon, exhibit a tensile strength of 1.7 GPa and a modulus of 173 GPa. This electrified synthesis simultaneously slashes production costs to ~US$13.52 kgCF−1 and carbon footprints to ~22.39 kgCO2 kgCF−1, offering a commercially viable pathway for high-volume industries such as automotive manufacturing. Our findings establish a circular carbon economy model that converts greenhouse gases into high-value structural materials while yielding hydrogen as a clean coproduct.

AB - Carbon fibres (CFs) are indispensable for lightweight structural engineering, yet their widespread adoption is stifled by the high cost and environmental toll of polyacrylonitrile (PAN) precursors. While substituting PAN with low-footprint alternatives such as lignin or carbon black reduces emissions, the resulting fibres typically suffer from mechanical degradation caused by poorly integrated fillers. Here we report an electrified carbon-fibre upgrading strategy that transforms low-cost, carbon-black-loaded PAN precursors into high-performance CFs by incorporating methane (CH4)-derived carbon. By using a porous, aligned fibril network as a Joule-heating element, we achieve rapid, high-temperature pyrolysis at 1,700 K that drives CH4 diffusion and densification of the internal microstructure. The resulting upgraded carbon fibres, comprising ~50 wt% CH4-derived carbon, exhibit a tensile strength of 1.7 GPa and a modulus of 173 GPa. This electrified synthesis simultaneously slashes production costs to ~US$13.52 kgCF−1 and carbon footprints to ~22.39 kgCO2 kgCF−1, offering a commercially viable pathway for high-volume industries such as automotive manufacturing. Our findings establish a circular carbon economy model that converts greenhouse gases into high-value structural materials while yielding hydrogen as a clean coproduct.

UR - https://www.scopus.com/pages/publications/105035768450

UR - https://www.scopus.com/pages/publications/105035768450#tab=citedBy

U2 - 10.1038/s41893-026-01815-w

DO - 10.1038/s41893-026-01815-w

M3 - Research Article

AN - SCOPUS:105035768450

SN - 2398-9629

JO - Nature Sustainability

JF - Nature Sustainability

ER -

Methane pyrolysis-enabled production of high-value carbon fibres

Abstract

UN SDGs

All Science Journal Classification (ASJC) codes

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