Your search keyword '"Wen, Yang"' showing total 3 results

1. Co/CoSe Junctions Enable Efficient and Durable Electrocatalytic Conversion of Polysulfides for High‐Performance Li–S Batteries.

Author

Wen, Yang, Shen, Zihan, Hui, Junfeng, Zhang, Huigang, and Zhu, Qingshan

Subjects

*LITHIUM sulfur batteries, *POLYSULFIDES, *CATALYTIC activity, *ENERGY storage, *ELECTRON mobility

Abstract

Lithium–sulfur (Li–S) batteries are regarded as promising candidates for next‐generation energy storage systems. However, the slow kinetics and shuttle effects of polysulfides hinder their practical applications. Designing high‐efficiency catalysts to enhance the kinetics and suppress shuttling is one major task for the building of durable Li–S batteries. Here, a Co/CoSe junction is reported to catalyzepolysulfide conversion efficiently because the junction has metallic electron mobility and field‐enhanced catalytic activity. The mechanistic investigation reveals that the difference in the work functions of Co and CoSe rearranges the charge distribution in the junction and strengthens the interaction between polysulfides and CoSe, thereby yielding high catalytic activity. In addition, the relative stability of CoSe, as compared to Co, renders the junction durable upon cycling; therefore, demonstrating long‐term catalytic activity. Such a junction makes full use of metal‐like conductivity and field‐enhanced catalysis and provides an alternative approach to enhancing the catalytic conversion of polysulfides. [ABSTRACT FROM AUTHOR]

Published

2023

2. Morphology‐Dependent Catalysis of CeO2‐Based Nanocrystal Model Catalysts.

Author

Wen, Yang, Huang, Qiuyu, Zhang, Zhenhua, and Huang, Weixin

Subjects

*CATALYSTS, *STRUCTURE-activity relationships, *CATALYSIS, *METAL catalysts, *ULTRAHIGH vacuum, *HETEROGENEOUS catalysts, *HETEROGENEOUS catalysis, *CERIUM oxides

Abstract

Comprehensive Summary: Recent progress in colloidal synthesis has realized the preparations of uniform nanocrystal (NC) model catalysts with rich and well‐controlled morphologies that were employed to explore structure‐activity relationships of powder catalysts, similar to single‐crystal‐based model catalysts under ultrahigh vacuum conditions but can work at the same conditions as powder catalysts without the "materials gap" and "pressure gap". In this perspective, the CeO2‐based NC model catalysts with various morphologies are included and their relevant progresses are critically reviewed. The detailed descriptions of morphology‐controlled synthesis and characterizations of uniform CeO2 NCs, and morphology‐dependent catalysis of CeO2‐based NC model catalysts containing pure CeO2 NCs, CeO2‐supported oxide catalysts, and CeO2‐supported metal catalysts, provide us a comprehensive cognition in CeO2‐involved catalytic reactions and also open up a new approach for the fundamental studies of complex heterogeneous catalysis. Finally, a concept of oxide‐based NC model catalysts and outlook of oxide NCs acting not only as model catalysts for the fundamental study but also as the support in tailoring structures and optimizing performance of oxide‐involved catalysts are discussed. [ABSTRACT FROM AUTHOR]

Published

2022

3. Leveraging Exchange Kinetics for the Synthesis of Atomically Precise Porous Catalysts.

Author

Ezazi, Andrew A., Gao, Wen‐Yang, and Powers, David C.

Subjects

*CATALYSTS, *KINETIC control, *METAL-organic frameworks, *TRANSITION metals, *CATALYSIS

Abstract

Metal‐organic frameworks (MOFs) have attracted significant attention as porous catalyst platforms due to the synthetic modularity of these materials and the diversity of lattice‐confined catalytic active sites that are readily embedded within periodic crystalline frameworks. MOFs offer platforms to heterogenize molecular catalysts, stabilize novel coordination motifs, and leverage confinement effects in catalysis. Crystallinity allows diffraction‐based methods to be employed in the characterization of these catalysts. Access to crystalline MOFs typically requires reversible construction of the metal−ligand (M−L) bonds that connect the SBUs, which provides a mechanism to anneal defects during crystallization. While the required M−L bond reversibility is often promoted by synthesis at elevated temperature, access to crystalline materials based on either transition metals with characteristic slow exchange kinetics or highly basic donor ligands remains a synthetic challenge. Here, we highlight synthetic strategies that leverage M−L exchange kinetics to access MOFs based on kinetically inert ions and extensions of these strategies to the assembly of atomically precise multimetallic materials. [ABSTRACT FROM AUTHOR]

Published

2021