Litcius/Paper detail

Restructuring at Au/AlOOH Interface Enables Enhanced CO <sub>2</sub> Photoreduction by Synergistically Optimizing Charge Separation and H <sub>2</sub> O Activation

Wenchao Shangguan, Guoqiang Li, Shidi Gui, Xiaodong Zhang, Sugang Meng, Shifu Chen, Yingxuan Li

2025Advanced Functional Materials19 citationsDOIOpen Access PDF

Abstract

Abstract Separating photoexcited holes in metallic nanostructure to drive H 2 O oxidation reaction to balance the CO 2 photoreduction reaction is highly desirable, but challenging. The bottleneck lies in the sluggish kinetics of both photoexcited hole transfer and H 2 O oxidation. Herein, this work demonstrates that the in situ reconstruction of n ‐type wide‐bandgap AlOOH‐supported Au nanoparticle heterogeneous photocatalyst, triggered by thermal and photothermal cooperative effect during photocatalytic reactions, facilitates the efficient CO 2 photoreduction through optimizing the Au 5 d ‐band holes separation and H 2 O activation. In situ and ex situ characterizations evidence restructuring at interfaces to form an ultrathin γ‐Al 2 O 3 nanolayer (≈2 nm thickness), which optimizes the energy band structure and promotes spontaneous transfer of photoexcited Au 5 d ‐band holes to the valence band of AlOOH, and prolongs the lifetime of electrons available for CO 2 reduction on Au. Furthermore, hydroxyl vacancies generated during restructuring process are demonstrated to promote H 2 O adsorption and lower the energy barrier for O 2 formation, supplying adequate protons for CO 2 protonation reduction and thereby boosting CO 2 photoreduction efficiency. This study offers valuable insights into the underlying mechanisms of utilizing n ‐type semiconductors to separate photoexcited d ‐band holes in metal nanoparticles.

Topics & Concepts

Materials scienceRestructuringChemical engineeringInterface (matter)Charge (physics)NanotechnologyComposite materialBusinessCapillary numberQuantum mechanicsEngineeringPhysicsCapillary actionFinanceAdvanced Photocatalysis TechniquesCatalytic Processes in Materials ScienceCopper-based nanomaterials and applications