Methanol Reforming for Hydrogen Production: Advances in Catalysts, Nanomaterials, Reactor Design, and Fuel Cell Integration

• Published in: ACS Engineering Au Vol. 5; no. 4; pp. 314 - 346
• Main Authors: Usman, Muhammad, Yamada, Tetsuya
• Format: Journal Article
• Language: English
• Published: American Chemical Society 20.08.2025
• Subjects: green hydrogen production; methanol reforming; fuel cell applications; reactor design and optimization; catalyst design and development; environmental catalysis; nanomaterials for hydrogen; sustainable energy systems
• ISSN: 2694-2488; 2694-2488
• DOI: 10.1021/acsengineeringau.5c00031

Methanol reforming has emerged as a leading pathway for on-demand hydrogen production, particularly for applications in portable power and fuel cells. This review offers a comprehensive analysis of methanol steam reforming (MSR), partial oxidation (POX), autothermal reforming (ATR), and recent integration strategies with renewable systems and fuel cells. Emphasis is placed on catalyst design, reaction mechanisms, reactors, operational parameters, and recent nanostructured catalyst innovations, such as single-atom catalysts (SACs), bimetallic, carbon nanotubes, perovskites, and alloy nanomaterials. This review critically evaluates recent progress, highlighting how tailored catalyst morphologies, metal–support interactions, and synthesis methods translate into enhanced methanol conversion, H2 selectivity, and CO suppression. Notably, low-temperature SACs and Zn-modified bimetallic systems exhibit remarkable performance metrics, pointing toward viable pathways for clean hydrogen production. Furthermore, emerging approaches like plasma-assisted dry reforming and chemical looping integration present promising solutions for CO2 utilization. Recent applications of artificial intelligence (AI) in catalyst screening and reaction modeling also show potential to accelerate the discovery of high-efficiency systems. By synthesizing these findings and identifying the gaps in current research, this review outlines future directions for scalable, low-emission methanol reforming technologies, aiming to support the global transition toward a hydrogen-based energy economy.