CATCH undergoes four work packages (WPs) of computational predictions, synthesis and refinement, in house and advanced characterizations, and mechanistic studies.
In general, the project has been well implemented according to the plan. In the period, 25 peer-reviewed journal articles, including 2 reviews, were published. In hetero-site selections (related to WP1, SO1) and materials realizations (related to WP2, SO2), after thoroughly surveying the 2D databases, computationally we have predicted various new 2D semiconductor matrices, such as 2D transition metal dichlorides, defective trihalide monolayers, and Ni tellurate. The tellurate was synthesized successfully in the lab. A machine learning algorithm was established to predict the heterojunctions with materials from 2D materials databases. Experimentally (related to WP2, SO2), shape-controlled synthesis has been performed and many synthetic materials have been realized. In activations, 0D decorates were loaded on to Ce metal–organic framework, nickel composites composed of flakes and 2D hydroxides. We realized high performances of photocatalysts, despite some of their morphologies are mixed. An apparent quantum efficiency of 20.45% at visible light region (420 nm) was reached for hydrogen evolution, and a removal rate of 95.6% for Cr (VI) under sunlight in 30 minutes. The 0D+2D Co3O4/Co(OH)2 was capable in photocatalytic hydrogen production and degradation of persistent microplastics under visible light. In mechanistic study (WPs 3,4 and SO3), the in-situ x-ray studies were performed along with density functional theory investigations of reaction intermediates during the photocatalysis.