Power-hydrogen coupling logic and roadmap for China under carbon neutrality

doi:10.16085/j.issn.1000-6613.2025-1220

Chemical Industry and Engineering Progress ›› 2025, Vol. 44 ›› Issue (11): 6127-6132.DOI: 10.16085/j.issn.1000-6613.2025-1220

• Perspective •

Power-hydrogen coupling logic and roadmap for China under carbon neutrality

PU Tian¹(), ZHOU Ying²^,³(), ZHANG Songlin²^,⁴, HU Jianqing⁴^,⁵, ZHOU Hongjun²^,⁴^,⁵^,⁶(), XU Chunming²^,⁵^,⁶

^1.College of New Energy and Materials, China University of Petroleum, Beijing 102249, China
^2.State Key Laboratory of Heavy Oil Processing, China University of Petroleum, Beijing 102249, China
^3.College of Science, China University of Petroleum, Beijing 102249, China
^4.Shandong Institute of Petroleum and Chemical Technology, Dongying 257061, Shandong, China
^5.Union Institute for Carbon Neutrality (State Key Laboratory of Heavy Oil Processing), Beijing 102249, China
^6.Yellow River Delta Sustainable Development Institute of Shandong Province, Dongying 257091, Shandong, China

Received:2025-08-25 Revised:2025-09-30 Online:2025-12-08 Published:2025-11-25
Contact: ZHOU Hongjun

碳中和下电氢耦合逻辑与中国路线图

蒲田¹(), 周颖²^,³(), 张松林²^,⁴, 胡建清⁴^,⁵, 周红军²^,⁴^,⁵^,⁶(), 徐春明²^,⁵^,⁶

^1.中国石油大学（北京）新能源与材料学院，北京 102249
^2.中国石油大学（北京）重质油全国重点实验室，北京 102249
^3.中国石油大学（北京）理学院，北京 102249
^4.山东石油化工学院，山东东营 257061
^5.重质油全国重点实验室碳中和联合研究院，北京 102249
^6.山东省黄河三角洲可持续发展研究院，山东东营 257091

通讯作者: 周红军
作者简介:蒲田（1993—），男，博士研究生，研究方向为低碳化工系统工程。E-mail: pascalpt@outlook.com。
周颖（1990—），女，副教授，研究方向为基于绿电绿氢的化工低碳技术。E-mail: zhou.ying@cup.edu.cn。
周颖（1990—），女，副教授，研究方向为基于绿电绿氢的化工低碳技术。E-mail: zhou.ying@cup.edu.cn。
基金资助:
国家自然科学基金青年科学基金(22408217);山东省自然科学基金青年基金(ZR2024QB402);碳中和联合研究院自主基金(CNIF20220204)

Abstract

Abstract:

This paper advances a system framework for coupling electricity and hydrogen and delineates an industrial transition pathway for China in pursuit of carbon neutrality. Anchored in the principle of "electricity for energy and hydrogen for materials", electricity is prioritized for high-temperature, strongly endothermic, and performance-critical operations (e.g., steam cracking, dehydrogenation, reforming). Electrified hydrocarbon cracking establishes an "e-olefin-H₂" pathway that co-produces olefins and low-carbon hydrogen, serving as a key enabler of emissions abatement in refining, steel, and ammonia while accelerating iteration and scale-up across the hydrogen value chain. Leveraging the Xinjiang-Inner Mongolia-Bohai Bay green-industrial corridor and associated long-distance power-export patterns, the pathway begins with direct connection to green power coupled with by-product hydrogen and then expands to cross-sector mitigation supported by a dedicated hydrogen pipeline network. Coordinated operation of the power, hydrogen, and natural-gas systems enables low-carbon peak-shaving and facilitates coal-power decarbonization. The study further assesses liquid-hydrogen-enabled superconducting co-transport and an integrated "power-hydrogen-cold" paradigm, whereby cryogenic exergy recovery can reconfigure cryogenic separations in ethylene and ammonia. On the policy side, a coherent constraint-incentive package is proposed-comprising green-power access and certificates, hydrogen taxonomy and pricing, carbon markets, and carbon capture, utilization, and storage (CCUS)-together with a sequenced sectoral transition (refining-ammonia-steel-cement-coal power) and the requisite infrastructure portfolio. The proposed pathway enhances system resilience and cost discipline, strengthens the low-carbon competitiveness of China's legacy industrial base, and yields spillover benefits for the East Asian refining landscape, providing an actionable, integrated technology-policy framework for deep industrial decarbonization.

Key words: carbon neutrality, e-olefin-H?, energy gas hub, integrated energy transmission pipeline, low-carbon transformation

摘要：

在碳中和愿景下系统提出“电-氢”协同机制和产业跃迁路径，遵循“电替能-氢承材”的基本逻辑，即电能优先配置于高温强吸热与高性能工业过程（如蒸汽裂解、脱氢、重整），通过电加热裂解烃类形成“电烯氢”通道，在生产烯烃的同时副产低碳氢，以此作为炼化、钢铁与合成氨减排的关键媒介并推动氢产业迭代。首先，结合新疆-内蒙-渤海湾绿色产业带与外输格局，提出以绿电直供与副产氢耦合基点，扩展至以氢管网为支撑的跨行业减排。通过电网-氢网-天然气网协同运行，实现低碳调峰与煤电脱碳。其次，探讨液氢超导“电氢冷”一体化集输与冷能回收对乙烯、合成氨深冷分离的重构潜力。再次，在政策层面建议构建以绿电接入规则与绿证、氢分类与定价、碳市场与CCUS为核心的约束-激励政策组合机制。最后，研判产业低碳转型时序优先级（炼化-合成氨-钢铁-水泥-煤电）及技术/资源/设施/政策等配套要素。该路径在保障系统韧性与成本可控的同时，可重塑中国传统工业的低碳竞争力，并对东亚炼化格局产生外溢效应，为传统工业深度碳减排提供规划性的技术-政策一体化框架。

关键词: 碳中和, 电烯氢, 能源气体岛, 综合能源输送管道, 低碳转型

CLC Number:

TK01

PU Tian, ZHOU Ying, ZHANG Songlin, HU Jianqing, ZHOU Hongjun, XU Chunming. Power-hydrogen coupling logic and roadmap for China under carbon neutrality[J]. Chemical Industry and Engineering Progress, 2025, 44(11): 6127-6132.

蒲田, 周颖, 张松林, 胡建清, 周红军, 徐春明. 碳中和下电氢耦合逻辑与中国路线图[J]. 化工进展, 2025, 44(11): 6127-6132.

Figures/Tables 2

References 13

[1]	Monolith. Monolith receives conditional approval for a one billion-dollar U.S department of energy loan[EB/OL]. (2021-12-23) [2025-09-30]. .
[2]	炭黑产业网. 纳米级导电炭黑，联产氢项目启动！[EB/OL]. (2025-07-29) [2025-09-30]. .
	Carbon Black Industry Network. Nano-grade conductive carbon black project launched, co-producing hydrogen[EB/OL].(2025-07-29)[2025-09-30]. .
[3]	BASF. BASF, SABIC and Linde join forces to realize the world’s first electrically heated steam cracker furnace[EB/OL]. (2021-03-24) [2025-08-15]. .
[4]	BASF. BASF, SABIC, and Linde celebrate the start-up of the world’s first large-scale electrically heated steam cracking furnace[EB/OL]. (2024-04-17) [2025-08-15]. .
[5]	Global Shell. DOW and Shell team up to develop electric cracking technology[EB/OL]. (2020-06-16) [2025-08-16]. .
[6]	周红军, 周颖, 徐春明. 中国碳达峰碳中和目标下炼化一体化新路径与实践[J]. 化工进展, 2022, 41(4): 2226-2230.
	ZHOU Hongjun, ZHOU Ying, XU Chunming. Exploration of refining and chemical integration under China’s dualcarbon target[J]. Chemical Industry and Engineering Progress, 2022, 41(4): 2226-2230.
[7]	周红军, 白保华, 周颖, 等. 碳中和目标下新型电力系统构建及发展路径研究——基于电化碳氢氧氮四元素能源体系的思考[J]. 新型电力系统, 2023(1): 19-31.
	ZHOU Hongjun, BAI Baohua, ZHOU Ying, et al. Research on the construction and development path of new power systems under the goal of carbon neutrality—Based on the energy system of e-CHNO[J]. New Type Power Systems, 2023(1): 19-31.
[8]	经济日报. 新能源乘用车渗透率超50%传递什么信号[EB/OL]. (2024-08-13) [2025-09-30]. .
	Daily Economic. What does it mean when new energy passenger vehicle penetration exceeds 50%?[EB/OL].(2024-08-13) [2025-09-30]. .
[9]	Holcim. Three holcim clean tech projects selected for EU innovation fund grants to decarbonize Europe[EB/OL]. (2023-07-14) [2025-09-30]. ,plant%20will%20be%20used%20to%20produce%20e%2Dmethanol.
[10]	惠生工程. 惠生工程斩获首个CO₂加氢合成甲醇万吨级示范项目EPC合同[EB/OL]. (2024-04-24) [2025-09-30]. .
	Engineering Wison. Wison Engineering secures EPC contract for pioneering ten-thousand-ton demonstration project converting CO₂ and hydrogen to methanol[EB/OL]. (2024-04-24) [2025-09-30]. .
[11]	薛城融媒体视频. 吉利创新中心二氧化碳加氢制甲醇千吨级中试项目开车仪式举行[EB/OL]. (2025-08-25) [2025-09-30]. .
	Xuecheng Media Video. Commissioning ceremony held for geely innovation center’s thousand-ton pilot project converting CO₂ and hydrogen to methanol [EB/OL]. (2025-08-25) [2025-09-30]. .
[12]	张国民, 陈建辉, 邱清泉, 等. 超导直流能源管道的研究进展[J]. 电工技术学报, 2021, 36(21): 4389-4398, 4428.
	ZHANG Guomin, CHEN Jianhui, QIU Qingquan, et al. Research progress on the superconducting DC energy pipeline[J]. Transactions of China Electrotechnical Society, 2021, 36(21): 4389-4398, 4428.
[13]	杨天慧, 信赢, 李文鑫. 满足电力与能源液体双重输送管道建设的超导材料需求和发展现状[J]. 中国电机工程学报, 2022, 42(S1): 215-225.
	YANG Tianhui, XIN Ying, LI Wenxin. Demand and development status of superconducting materials to meet the construction of dual transmission pipelines for power and energy liquids[J]. Proceedings of the CSEE, 2022, 42(S1): 215-225.

[1]	LIU Kefeng, DONG Weigang, HU Xuesheng, LIU Taoran, ZHOU Huaqun, SHI Wen, WAN Zi’an, GAO Fei. Policies and measures to promote the development of CCUS [J]. Chemical Industry and Engineering Progress, 2025, 44(9): 4879-4897.
[2]	ZHOU Ying, BAI Baohua, PU Tian, ZHOU Enze, HU Jianqing, ZHANG Songlin, ZHOU Hongjun, XU Chunming. Construction and demonstration of net-zero industrial parks [J]. Chemical Industry and Engineering Progress, 2025, 44(7): 4282-4286.
[3]	WANG Wanze, DING Jun, YAN Xu, CHEN Guoqiang. Renewable source utilization and biomanufacturing based on halophilic chassis [J]. Chemical Industry and Engineering Progress, 2025, 44(5): 2421-2428.
[4]	SONG Xingfei, JIA Xin, AN Ping, HAN Zhennan, XU Guangwen. Development of science and technology in thermochemical reaction engineering [J]. Chemical Industry and Engineering Progress, 2024, 43(7): 3513-3533.
[5]	HAN Wei, HAN Hengwen, CHENG Wei, TANG Weijian. Research progress of biomass fuels technology driven by carbon neutrality [J]. Chemical Industry and Engineering Progress, 2024, 43(5): 2463-2474.
[6]	HUANG Sheng, YANG Zhenli, LI Zhenyu. Analysis of optimization path of developing China's hydrogen industry [J]. Chemical Industry and Engineering Progress, 2024, 43(2): 882-893.
[7]	SHAO Bin, LI Su, MA Rongting, XIE Zhicheng, GAO Zihao, JIA Zhonghao, WANG Wenhui, SUN Zheyi, HU Jun. Catalytic hydrogenation of carbonate minerals: A promising pathway to carbon neutrality for industries with intensive carbon emissions [J]. Chemical Industry and Engineering Progress, 2024, 43(11): 5995-6009.
[8]	HAN Hengwen, HAN Wei, CHENG Wei. Development trend of synthetic fuel technology driven by carbon neutrality [J]. Chemical Industry and Engineering Progress, 2024, 43(10): 5457-5466.
[9]	CHEN Chongming, ZENG Siming, LUO Xiaona, SONG Guosheng, HAN Zhongge, YU Jinxing, SUN Nannan. Preparation and performance of carbon supported potassium-based CO₂ adsorbent derived from hyper-cross linked polymers [J]. Chemical Industry and Engineering Progress, 2023, 42(3): 1540-1550.
[10]	YAO Lun, ZHOU Yongjin. Progress in microbial utilization of one-carbon feedstocks for biomanufacturing [J]. Chemical Industry and Engineering Progress, 2023, 42(1): 16-29.
[11]	HU Bing, XU Lijun, HE Shan, SU Xin, WANG Jiwei. Researching progress of hydrogen production by PEM water electrolysis under the goal of carbon peak and carbon neutrality [J]. Chemical Industry and Engineering Progress, 2022, 41(9): 4595-4604.
[12]	ZHOU Ying, ZHOU Hongjun, XU Chunming. Exploration of the development path for the hydrogen energy [J]. Chemical Industry and Engineering Progress, 2022, 41(8): 4587-4592.
[13]	YANG Xueping. Exploration on technical path of modern coal chemical industry under the background of carbon neutralization [J]. Chemical Industry and Engineering Progress, 2022, 41(7): 3402-3412.
[14]	ZHOU Hongjun, ZHOU Ying, XU Chunming. Exploration of the CO₂ conversion under China’s carbon neutrality goal [J]. Chemical Industry and Engineering Progress, 2022, 41(6): 3381-3385.
[15]	HUANG Sheng, WANG Jingyu, LI Zhenyu. Analysis of green and low-carbon development path of petroleum and chemical industry under the goal of carbon neutrality [J]. Chemical Industry and Engineering Progress, 2022, 41(4): 1689-1703.

Power-hydrogen coupling logic and roadmap for China under carbon neutrality

碳中和下电氢耦合逻辑与中国路线图

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