Here we introduce a novel light-induced destabilization mechanism for hydrogen storage reaction of borohydrides under ambient conditions via photogenerated vacancies in LiH.
Our Redeem Photo Reactor can produce green hydrogen from different feed sources, including fresh, contaminated, and salt water, ammonia, or liquid organic hydrogen carriers (LOHCs), making it the most versatile solution on the market.
Here, the authors report a design for a photocatalytic water-splitting system that efficiently produces hydrogen and oxygen in separate cells.
The present review offers a strategic roadmap for overcoming conventional photocatalyst limitations and emphasizes recent advancements in hybrid photocatalysts, thereby addressing electrode and topology-associated challenges for sustainable hydrogen (H₂) production and storage.
This paper provides a comprehensive review of the latest advancements in photothermal-assisted solar hydrogen production systems, with a focus on the application of photothermal effects in diverse solar hydrogen production systems.
Our approach introduces a fresh perspective for the dehydrogenation of liquid hydrogen carriers, encompassing formic acid, hydrazine hydrate, and so on, and concurrently guarantees exceptional hydrogen release capabilities and excellent hydrogen storage density.
Xiaoyue Zhang, Chaoqun Li, Jikai Ye, Xuechun Hu, Wei Chen, Fang Fang, Dalin Sun, Yongfeng Liu*, Xuebin Yu*, and Guanglin Xia*, Light-Enabled Reversible Hydrogen Storage of Borohydrides Activated by Photogenerated Vacancies, J. Am. Chem. Soc. 2025
This section provides a detailed overview of three various configurations of PEC-MH setups that combine solar hydrogen production and storage with its subsequent hydrogen release via hydrogen-to-electricity conversion (type B), and thereby can operate as solar-driven rechargeable batteries.
The photocatalytic process plays a vital role in the direct conversion and storage of renewable solar energy into green hydrogen (H 2) fuel, a long-term and sustainable technology pathway with the potential for limiting the growth of global carbon emissions.
This work presents the photo-induced liberation of H2 from formic acid (FA) as a liquid H2 carrier, using visible light and well-established 5 wt% palladium nanoparticles supported over carbon (Pd/C).
Here we introduce a novel light-induced destabilization mechanism for hydrogen storage reaction of borohydrides under ambient conditions via photogenerated vacancies in LiH.
