Efficient Schottky Junction Construction in Metal‐Organic Frameworks for Boosting H(2) Production Activity

Manipulation of the co‐catalyst plays a vital role in charge separation and reactant activation to enhance the activity of metal‐organic framework‐based photocatalysts. However, clarifying and controlling co‐catalyst related charge transfer process and parameters are still challenging. Herein, three parameters are proposed, V (transfer) (the electron transfer rate from MOF to co‐catalyst), D (transfer) (the electron transfer distance from MOF to co‐catalyst), and V (consume) (the electron consume rate from co‐catalyst to the reactant), related to Pt on UiO‐66‐NH(2) in a photocatalytic process. These parameters can be controlled by rational manipulation of the co‐catalyst via three steps: i) Compositional design by partial substitution of Pt with Pd to form PtPd alloy, ii) location control by encapsulating the PtPd alloy into UiO‐66‐NH(2) crystals, and iii) facet selection by exposing the encapsulated PtPd alloy (100) facets. As revealed by ultrafast transient absorption spectroscopy and first‐principles simulations, the new Schottky junction (PtPd (100)@UiO‐66‐NH(2)) with higher V (transfer) and V (consume) exhibits enhanced electron‐hole separation and H(2)O activation than the traditional Pt/UiO‐66‐NH(2) junction, thereby leading to a significant enhancement in the photoactivity.