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Grain-boundary-rich Pt nanoparticle assembly for catalytic hydrogen sensing at room temperature

16 December 2021, Version 1
Working Paper
This content is an early or alternative research output and has not been peer-reviewed by Cambridge University Press at the time of posting.

Abstract

We report a facile method of synthesizing grain-boundary(GB)-rich platinum nanoparticle assembly. GBs are formed between platinum nanoparticles during their random collision and attachment in solution driven by water electrolysis. The GB-rich nanoparticle assembly exhibits ~400-fold higher catalytic hydrogen oxidation rate than platinum nanoparticles before assembly, enabling catalytic hydrogen sensing at room temperature without external heating. Our sensor also demonstrates fast response/recovery (~7 s at >1% H2), nearly no signal variation during a 280-hour-long stability test, and high selectivity toward hydrogen over 36 interference gases. Furthermore, this sensor can be easily fabricated from commercial thermometers at a low cost (< $5 per unit). Theoretical calculation results reveal that the high performance of GB-rich platinum nanoparticle assembly arises from tensile strain at the GBs.

Keywords

Grain boundary
Nanoparticle
Catalysis
Hydrogen Sensing

Supplementary materials

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Description
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Supporting information
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Supporting information
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Movie 1
Description
Demonstration of H2 leak detection using a drone sensing platform.
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Movie 2
Description
Demonstration of detection of 2% H2 in air.
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Now Published

Grain‐Boundary‐Rich Noble Metal Nanoparticle Assemblies: Synthesis, Characterization, and Reactivity [opens in a new tab]
Xin Geng, Shuwei Li, Jaeyoung Heo, Yi Peng, Wenhui Hu, Yanchao Liu, Jier Huang, Yang Ren, Dongsheng Li, Liang Zhang, Long Luo journal article
Advanced Functional Materials
Online publication date: Jun 15, 2022

Version History

Dec 16, 2021 Version 1

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The content is available under CC BY 4.0 [opens in a new tab]

DOI

10.26434/chemrxiv-2021-tm34c
D O I: 10.26434/chemrxiv-2021-tm34c [opens in a new tab]

Funding

U.S. Department of Energy
78705; DE-AC02-06CH11357; KC0203020:67037;DE-AC05-76RL01830
National Science Foundation
CHE-1943737
National Natural Science Foundation of China
22103047
National Science Foundation
DMR-1654140

Author’s competing interest statement

U.S. provisional patent application (no. 63/278,451) based on the technology described in this work was filed on 11 Nov 2021 by L.L. and X.G. at Wayne State University.

Ethics

The author(s) have declared ethics committee/IRB approval is not relevant to this content

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