General negative pressure annealing approach for creating ultra-high-loading single atom catalyst libraries

Wang, Yi; Li, Chongao; Han, Xiao; Bai, Jintao; Wang, Xuejing; Zheng, Lirong; Hong, Chunxia; Li, Zhijun; Bai, Jinbo; Leng, Kunyue; Lin, Yue; Qu, Yunteng

doi:10.1038/s41467-024-50061-1

Nat Commun

2024

DOI: 10.1038/s41467-024-50061-1

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General negative pressure annealing approach for creating ultra-high-loading single atom catalyst libraries

Yi Wang,

Chongao Li,

Xiao Han

et al.

Abstract: Catalyst systems populated by high-density single atoms are crucial for improving catalytic activity and selectivity, which can potentially maximize the industrial prospects of heterogeneous single-atom catalysts (SACs). However, achieving high-loading SACs with metal contents above 10 wt% remains challenging. Here we describe a general negative pressure annealing strategy to fabricate ultrahigh-loading SACs with metal contents up to 27.3–44.8 wt% for 13 different metals on a typical carbon nitride matrix. Fur… Show more

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Cited by 10 publications

References 41 publications

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Nano‐High Entropy Materials in Electrocatalysis

Yan,

Zhou,

Wang

2024

Adv Funct Materials

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High entropy materials (HEMs) compositing of at least five elements have gained widespread attention in the field of electrocatalysis due to their tunable activities and high stability. These intrinsic properties can be further highlighted when the size of HEMs comes to the nanoscale. In nanostructured HEMs, the fascinating properties including large composition space, multi‐element synergy, and high configuration entropy are expected to endow nano‐HEMs with excellent catalytic activity and stability, thus providing greater potential for the design of advanced electrocatalysts. In this review, nano‐HEMs are differentiated in detail in dimensions and the common synthesis methods are summarized. Additionally, from the perspective of the complex nanostructure‐performance relationship, the applications of nano‐HEMs in electrocatalysis systems, including water‐splitting (hydrogen evolution reaction (HER), oxygen evolution reaction (OER)), hydrogen oxidation reaction (HOR), oxygen reduction reaction (ORR), carbon dioxide reduction reaction (CO2RR), nitrogen reduction reaction (NRR) and alcohol oxidation reaction (AOR) are discussed. Finally, the main challenges faced by nano‐HEMs electrocatalysis are underscored. This review is expected to provide more insights into understanding and developing efficient electrocatalytic materials for practical applications.

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Nano‐High Entropy Materials in Electrocatalysis

Yan,

Zhou,

Wang

2024

Adv Funct Materials

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Ultrahigh Single Au Atoms Loaded Porous Aromatic Frameworks for Enhanced Photocatalytic Hydrogen Evolution

Yang,

Xiao,

Jiang

et al. 2024

Advanced Materials

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Supported single‐atom catalysts (SACs) are promising in heterogeneous catalysis because of their atom economy, unusual transformations, and mechanistic clarity. The metal SAs loading, however, limits the catalytic efficiency. Herein, an in situ pre‐metallated monomer‐based preparation strategy is shown to achieve ultrahigh Au SAs loading in catalyst formations. The polymerization of single‐atom loaded monomers yield a new porous aromatic framework (PAF‐164) with Au SAs loading up to a record high 45.3 wt.%. SACs of Au‐PAFs exhibit excellent photocatalytic activity in hydrogen (H2) evolution, and the H2 evolution rate of Au100%‐SAs‐PAF‐164 can reach 4.82 mmol g−1 h−1 with great recyclability.

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An Oriented Diffusion Strategy to Configure All‐Region Ultrahigh‐Density Metal Single Atoms for High‐Capacity Sodium Storage

Ai,

Zhao,

Song

et al. 2024

Advanced Materials

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Single‐atom metals (SAMs), despite being promising for high‐utilization catalysis, biomedicine, and energy storage, usually suffer from limited catalytic performance caused by low metal loading. Herein, via an oriented diffusion strategy, all‐region ultrahigh‐loading (18.9 wt.%) Sn‐SAMs over carbon nanorings matrix (Sn‐SAMs@CNR) are initially achieved based on the transformation of a g‐C3N4@SnO2@polydopamine ring‐like nested structure. The formation process of Sn‐SAMs involves a critical conversion from oxygen‐coordination (SnO2) to nitrogen‐coordination (Sn‐N4) and simultaneous anti‐Osterwalder ripening promoted under spatial confinement. Notably, the g‐C3N4‐derived N‐containing gaseous intermediates dynamically drive the oriented diffusion (inside‐out diffusion) of Sn‐SAMs across the carbon nanorings, realizing an all‐region ultrahigh loading of SAMs throughout the carbon matrix. This strategy is also applied to other metal materials (Fe, Co, Ni, Cu, and Sb), and features excellent universality. When applied as the anode for sodium‐ion batteries, experimental analyses and theoretical calculations demonstrate that high‐loading Sn‐N4 active sites significantly optimize electron density distribution and improve reaction kinetics. Consequently, Sn‐SAMs@CNR exhibits outstanding durability of 364 mAh g−1 even after 5000 cycles with an impressively low (0.00068%) capacity decay per cycle. This work opens up a universally new avenue for all‐region ultrahigh loading of SAMs to carbon matrix for high‐performance energy storage.

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General negative pressure annealing approach for creating ultra-high-loading single atom catalyst libraries

Cited by 10 publications

References 41 publications

Nano‐High Entropy Materials in Electrocatalysis

Nano‐High Entropy Materials in Electrocatalysis

Ultrahigh Single Au Atoms Loaded Porous Aromatic Frameworks for Enhanced Photocatalytic Hydrogen Evolution

An Oriented Diffusion Strategy to Configure All‐Region Ultrahigh‐Density Metal Single Atoms for High‐Capacity Sodium Storage

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