Advances in Materials and Manufacturing for Scalable and Decentralized Green Hydrogen Production Systems
スケーラブルで分散型のグリーン水素製造システムのための材料と製造の進歩 (AI 翻訳)
G. Szabó, Florina-Ambrozia Coteț, Sára Ferenci, L. Szabó
🤖 gxceed AI 要約
日本語
本論文は、グリーン水素の大規模製造に必要な材料と製造技術の進展を概観する。PEM、アルカリ、固体酸化物電解のボトルネックを分析し、ロールツーロールコーティングやデジタルツインなどの量産技術が、分散型水素システムと大規模プラントの両方に対応できると論じる。材料耐久性と製造精度の同時最適化の重要性を強調する。
English
This paper reviews advances in materials and manufacturing for green hydrogen production, focusing on scalability from GW to TW levels and compatibility with decentralized renewable systems. It analyzes bottlenecks in electrolysis technologies and highlights emerging fabrication strategies such as roll-to-roll coating and digital-twin quality assurance. The authors emphasize joint optimization of material durability, manufacturing precision, and system control for reliable hydrogen supply.
Unofficial AI-generated summary based on the public title and abstract. Not an official translation.
📝 gxceed 編集解説 — Why this matters
日本のGX文脈において
日本は水素基本戦略でグリーン水素の大量導入を掲げており、本論文の製造スケーラビリティや分散型システムに関する知見は、国内の水素サプライチェーン構築やSSBJ開示における技術的裏付けとして有用。
In the global GX context
As global hydrogen deployment accelerates, this paper provides a comprehensive technical overview of manufacturing scalability critical for meeting climate targets. It bridges the gap between laboratory innovations and industrial production, relevant to ISSB-aligned disclosures on technology readiness and transition risk.
👥 読者別の含意
🔬研究者:Researchers gain a systematic analysis of material and manufacturing bottlenecks across electrolysis technologies and emerging solutions.
🏢実務担当者:Practitioners can identify scalable manufacturing pathways and quality assurance methods for green hydrogen systems.
🏛政策担当者:Policymakers can reference the paper to understand infrastructure and investment needs for hydrogen production at scale.
📄 Abstract(原文)
The expansion of green hydrogen requires technologies that are both manufacturable at a GW-to-TW power scale and adaptable for decentralized, renewable-driven energy systems. Recent advances in proton exchange membrane, alkaline, and solid oxide electrolysis reveal persistent bottlenecks in catalysts, membranes, porous transport layers, bipolar plates, sealing, and high-temperature ceramics. Emerging fabrication strategies, including roll-to-roll coating, spatial atomic layer deposition, digital-twin-based quality assurance, automated stack assembly, and circular material recovery, enable high-yield, low-variance production compatible with multi-GW power plants. At the same time, these developments support decentralized hydrogen systems that demand compact, dynamically operated, and material-efficient electrolyzers integrated with local renewable generation. The analysis underscores the need to jointly optimize material durability, manufacturing precision, and system-level controllability to ensure reliable and cost-effective hydrogen supply. This paper outlines a convergent approach that connects critical-material reduction, high-throughput manufacturing, a digitalized balance of plant, and circularity with distributed energy architectures and large-scale industrial deployment.
🔗 Provenance — このレコードを発見したソース
- semanticscholar https://doi.org/10.3390/jmmp10010028first seen 2026-05-15 19:30:33
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