Mechanochemical Engineering of Interfacial Charge-Transfer Architectures for Pollutant Degradation, Carbon Capture, and Hydrogen Generation
汚染物質分解、炭素回収、水素生成のための界面電荷移動アーキテクチャのメカノケミカル工学 (AI 翻訳)
Alvin Lim Teik Zheng, Ellie Yi Lih Teo, Omar Faruqi Marzuki, Pang Hung Yiu, Supakorn Boonyuen, Eric Lim Teik Chung, Yoshito Andou
🤖 gxceed AI 要約
日本語
本レビューは、メカノケミカルボールミリングが光触媒システムにおける界面電荷移動アーキテクチャを設計する精密戦略としてどのように進化したかを批判的に検討する。ボールミリングによって誘起される固体-固体相互作用が、汚染物質分解、水素生成、CO2還元に用いられるヘテロ接合全体での電荷分離、酸化還元保持、電子利用をどのように制御するかに焦点を当てる。
English
This review critically examines how mechanochemical ball milling has evolved into a precision strategy for engineering interfacial charge-transfer architectures in photocatalytic systems, focusing on how ball-milling-induced solid-solid interactions regulate charge separation, redox retention, and electron utilization across heterojunctions employed in pollutant degradation, hydrogen evolution, and CO2 reduction.
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
日本は水素社会実現とカーボンリサイクルに注力しており、本論文の光触媒技術は特に水素生成とCO2還元の効率向上に寄与する可能性がある。メカノケミカル手法はスケーラビリティに課題があるが、日本の素材産業との連携で実用化が期待される。
In the global GX context
This paper addresses global interest in green hydrogen and carbon capture/utilization through advanced photocatalysis. The mechanochemical approach offers a scalable, solvent-free route to engineer efficient photocatalytic interfaces, which is relevant for renewable energy and CO2 reduction technologies worldwide.
👥 読者別の含意
🔬研究者:Provides a comprehensive overview of mechanochemical strategies for designing charge-transfer architectures, useful for researchers in photocatalysis and materials science.
📄 Abstract(原文)
Abstract Mechanochemical ball milling has progressed beyond a solvent-free synthesis route into a precision strategy for programming interfacial charge-transfer architectures in photocatalytic systems. This review critically examines how ball-milling-induced solid-solid interactions regulate charge separation, redox retention, and electron utilization across heterojunctions employed in pollutant degradation, hydrogen evolution, and CO 2 reduction. Rather than cataloguing material combinations, this mini review centers on how mechanochemistry stabilizes distinct charge-transfer topologies, including Type II polymer heterojunctions, Z-and S-scheme systems, Schottky contacts, and ohmic interfaces, through enforced electronic coherence, defect-interface coupling, and Fermi-level equilibration. Quantitative comparisons reveal that catalytic performance scales with interface-governed charge regulation rather than compositional complexity, with ball-milled systems achieving hydrogen evolution rates exceeding 103 -104 μmol g-1 h -1 and near-complete pollutant removal under visible light (VL).By integrating kinetic data, spectroscopic evidence, and theoretical insights, this review establishes mechanochemical ball milling as a charge-architecture engineering tool capable of deterministically shaping photocatalytic function. Remaining challenges related to scalability, defect stability, and real-matrix performance are discussed to delineate pathways toward industrially relevant, interface-programmed photocatalysis.
🔗 Provenance — このレコードを発見したソース
- openalex https://doi.org/10.1088/2631-8695/ae7cdefirst seen 2026-06-14 04:52:11 · last seen 2026-06-14 04:52:24
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