推动粉红氢技术发展的新兴技术创新

Emerging Technological Innovations Driving the Advancement of Pink Hydrogen

出版日期: 2026年02月10日 | 出版商:

Frost & Sullivan | 英文 47 Pages | 商品交期: 最快1-2个工作天内

价格

简介目录

探索利用核能实现规模化清洁氢气生产的途径。

利用核能发电的电力、热能或二者结合製取的粉红氢，作为可扩展的低碳全球脱碳方案，正备受关注。包括碱性电解、质子交换膜电解和固体氧化物电解（SOEC）系统在内的核能一体化电解技术的快速发展，正在实现更深层的热耦合、更高的转化效率和更强的运作可靠性。同时，高温热化学循环技术的进步，例如硫碘製程和混合硫工艺，正在显着提高核子反应炉相容性、氢气产量和整体核能性能。核子反应炉设计、传热整合和混合核氢工程的创新，正在增强粉红氢的扩充性和成本效益。总而言之，这些技术进步使核氢生产成为未来脱碳能源结构的核心支柱，并为新兴的氢能经济做出重要贡献。

本研究全面回顾了推动这项进展的技术创新，重点关注核电电解混合氢气系统和热化学氢气系统。研究阐明了多种氢气路径的性能特性、能源效率提升和生产成本。此外，研究还展望了新兴创新生态系统（包括主要企业、突破性技术、资金筹措倡议和全球专利活动）的未来发展前景，以及整合核子反应炉技术、电解技术进步和热化学製程如何加速粉红氢在未来清洁能源系统中的应用。

粉红氢：支持净零氢经济
核能发电使氢能经济的实现成为可能。
低温水电电解：碱性电解混合
低温水电电解：PEM电解混合
高温水电电解：SOEC混合型
热化学製氢：硫碘（SI）循环
热化学电解混合－混合硫（西屋）循环
利用核能製氢方法的比较评估。

创新生态系统

用于製氢的堆迭式固态氧化物电解池
SOEC 能够以低能耗实现清洁氢气生产。
IMSR：先进能源与氢能核子反应炉
其他推广核能氢技术的公司

主要资金筹措倡议和专利状况

全球相关人员的资金筹措倡议
中国在核能氢技术专利申请方面处于领先地位。

成长机会领域

成长机会1：偏远和无电网地区的粉红色氢能係统
成长机会2：次世代水素製造のための高温电解および热化学サイクル
成长机会3：利用氢能实现工业脱碳

附录与后续步骤

成长机会带来的益处和影响
下一步
免责声明

简介目录

Product Code: DB6F

Exploring Nuclear-Enabled Pathways for Scalable, Clean Hydrogen Production

Pink hydrogen, produced using electricity, heat, or a combination of both from nuclear power has emerged as a scalable and low-carbon pathway for global decarbonization. Rapid advancements in nuclear-integrated electrolysis, including alkaline, PEM, and SOEC systems, are enabling deeper thermal coupling, improved conversion efficiency, and enhanced operational reliability. At the same time, progress in high-temperature thermochemical cycles, such as the sulfur-iodine and hybrid-sulfur processes, is driving significant gains in reactor compatibility, hydrogen yield, and overall system performance. Innovations in reactor design, heat-transfer integration, and hybrid nuclear-hydrogen engineering are strengthening the scalability and cost-effectiveness of pink hydrogen. Collectively, these technological developments position nuclear-enabled hydrogen production as a central pillar of future decarbonized energy architectures and an essential contributor to the emerging hydrogen economy.

This study provides a comprehensive review of technological innovations propelling its advancement, focusing on both nuclear-electrolysis hybrids and thermochemical water-splitting systems; multiple production pathways, highlighting their performance attributes, energy efficiency improvements and production cost; the emerging innovation ecosystem, including leading companies, breakthrough technologies, funding initiatives, and global patent activity; and forward-looking perspectives on how integrated reactor technologies, electrolysis advancements, and thermochemical processes can accelerate the adoption of pink hydrogen in future clean energy systems.

Strategic Imperatives

Why Is It Increasingly Difficult to Grow?
The Strategic Imperative 8-TM: Factors Creating Pressure on Growth
The Strategic Imperative 8-TM
The Impact of the Top 3 Strategic Imperatives on the Pink Hydrogen Industry
Growth Opportunities Fuel the Growth Pipeline Engine-TM
Research Methodology

Growth Opportunity Analysis

Scope of Analysis
Segmentation

Growth Generator

Growth Drivers
Growth Restraints

Technology Snapshot

Pink Hydrogen: Powering the Net-Zero Hydrogen Economy
Nuclear Power to be an Enabler of the Hydrogen Economy
Low-Temperature Water Electrolysis: Alkaline Electrolysis Hybrid
Low-Temperature Water Electrolysis: PEM Electrolysis Hybrid
High-Temperature Water Electrolysis: SOEC Hybrid
Thermochemical Water Splitting: Sulfur-Iodine (S-I) Cycle
Thermochemical Electrolysis Hybrid - Hybrid Sulfur (Westinghouse) Cycle
Comparative Evaluation of Nuclear-Enabled Hydrogen Production Methods

Innovation Ecosystem

Stackable SOEC for Hydrogen Production
SOEC Offering Low-Energy Consumption for Clean Hydrogen Production
IMSR: Advanced Nuclear Reactor for Energy and Hydrogen
Other Companies Advancing Nuclear-Powered Hydrogen Technology

Key Funding Initiatives and Patent Landscape

Funding Initiatives By Global Stakeholders
China is at the Forefront of Patent Filings in Nuclear-Powered Hydrogen Technology

Growth Opportunity Universe

Growth Opportunity 1: Pink Hydrogen Systems in Remote and Off-Grid Locations
Growth Opportunity 2: High-Temperature Electrolysis and Thermochemical Cycles for Next-Generation Hydrogen Production
Growth Opportunity 3: Hydrogen-Enabled Industrial Decarbonization