Electrochemically Li-intercalated TiO2 nanoparticles for High performance photocatalytic production of hydrogen

Lithiation: Advancing Material Synthesis and Structural Engineering for Emerging Applications

Lithiation, a process of inserting lithium ions into a host material, is revolutionizing nanomaterials synthesis and structural engineering as well as enhancing their performance across emerging applications, particularly valuable for large-scale synthesis of high-quality low-dimensional nanomaterials. Through a systematic investigation of the synthetic strategies and structural changes induced by lithiation, this review aims to offer a comprehensive understanding of the development, potential, and challenges associated with this promising approach. First, the basic principles of lithiation/delithiation processes will be introduced. Then, the recent advancements in the lithiation-induced structure changes of nanomaterials, such as morphology tuning, phase transition, defect generation, etc., will be stressed, emphasizing the importance of lithiation in structural modulation of nanomaterials. With the tunable structures induced by the lithiation, the properties and performance in electrochemical, photochemical, electronic devices, bioapplications, etc. will be discussed, followed by outlining the current challenges and perspectives in this research area.

Photocatalytic Reforming for Hydrogen Evolution: A Review

Hydrogen is considered to be an ideal energy carrier to achieve low-carbon economy and sustainable energy supply. Production of hydrogen by catalytic reforming of organic compounds is one of the most important commercial processes. With the rapid development of photocatalysis in recent years, the applications of photocatalysis have been extended to the area of reforming hydrogen evolution. This research area has attracted extensive attention and exhibited potential for wide application in practice. Photocatalytic reforming for hydrogen evolution is a sustainable process to convert the solar energy stored in hydrogen into chemical energy. This review comprehensively summarized the reported works in relevant areas, categorized by the reforming precursor (organic compound) such as methanol, ethanol and biomass. Mechanisms and characteristics for each category were deeply discussed. In addition, recommendations for future work were suggested.