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Graphene-confined ultrafast radiant heating for overcoming the trade-off between subnanometer size and high metal loading in meta cluster catalysts

06.14.23 | Science China Press

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Schematic and application of the GCURH method.
The GCURH method is capable of providing microseconds scale of high-temperature pulse with a heating/cooling rate of 10^9 °C/s, and thus be applied to precisely synthesis of sub-nanometer metal cluster catalysts with high metal loadings. Credit: ©Science China Press

This study is led by Prof. Zhong-Qun Tian (Xiamen University) and Prof. Kostya S. Novoselov (National University of Singapore). Originating from the ultrafast laser-to-thermal conversion capacity and the impermeable, flexible features of graphene, Dr. Ye-Chuang Han (primary author) and Prof. Zhong-Qun Tian conceived the idea and chosen graphene as the diffusion-constrained nanoreactor for high-temperature reactions. In one pulse of nanosecond laser irradiation, they found the irradiated area of graphene achieves a surprisingly high heating/cooling rate of 10^9 °C/s, and named the heating method as graphene-confined ultrafast radiant heating (GCURH) (see image below). Furthermore, through collaborating with Dr. Jun Yi (co-first author) and Prof. Kostya S. Novoselov, they performed the theoretical calculations and found that such an ultrafast cooling process is in accord with Stefan-Boltzmann law, and radiation become the primary mode of energy release at elevated temperatures.

Given that thermally activated ultrafast diffusion, collision and combination of metal atoms are fundamental processes for synthesizing burgeoning subnanometer metal clusters, and no method has allowed the kinetically controllable synthesis of subnanometer metal clusters while not compromise metal loading. Dr. Ye-Chuang Han and Dr. Beibei Pang (co-first author, University of Science and Technology of China) demonstrated that kinetics-driven GCURH method is capable of synthesizing subnanometer Co cluster catalysts with high metal loading up to 27.1 wt% by pyrolyzing a Co-based metal-organic framework in microseconds, representing one of the highest size-loading combinations and the quickest rate for MOF pyrolysis in the reported literature.

Overall, this work provides a general strategy to overcome the trade-off between ultrasmall size and high loading in metal cluster catalysts, and holds great promise for the upcoming industrial applications of cluster catalysts.

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See the article:

Graphene-confined ultrafast radiant heating for high-loading subnanometer metal cluster catalysts

https://doi.org/10.1093/nsr/nwad081

National Science Review

10.1093/nsr/nwad081

Keywords

Physical Sciences

Article Information

Journal
National Science Review
DOI
10.1093/nsr/nwad081

Contact Information

Bei Yan
Science China Press
yanbei@scichina.org

How to Cite This Article

APA:
Science China Press. (2023, June 14). Graphene-confined ultrafast radiant heating for overcoming the trade-off between subnanometer size and high metal loading in meta cluster catalysts. Brightsurf News. https://www.brightsurf.com/news/8J495JWL/graphene-confined-ultrafast-radiant-heating-for-overcoming-the-trade-off-between-subnanometer-size-and-high-metal-loading-in-meta-cluster-catalysts.html
MLA:
"Graphene-confined ultrafast radiant heating for overcoming the trade-off between subnanometer size and high metal loading in meta cluster catalysts." Brightsurf News, Jun. 14 2023, https://www.brightsurf.com/news/8J495JWL/graphene-confined-ultrafast-radiant-heating-for-overcoming-the-trade-off-between-subnanometer-size-and-high-metal-loading-in-meta-cluster-catalysts.html.