Mesoporous PdBi nanocages for enhanced electrocatalytic performances by all-direction accessibility and steric site activation

Dawei Du; Qinghong Geng; Lian Ma; Siyu Ren; Jun Xuan Li; Weikang Dong; Qingfeng Hua; Longlong Fan; Ruiwen Shao; Xiaoming Wang; Cuiling Li; Yusuke Yamauchi

doi:10.1039/d1sc06314f

Mesoporous PdBi nanocages for enhanced electrocatalytic performances by all-direction accessibility and steric site activation

Dawei Du, Qinghong Geng, Lian Ma, Siyu Ren, Jun Xuan Li, Weikang Dong, Qingfeng Hua, Longlong Fan, Ruiwen Shao, Xiaoming Wang, Cuiling Li^*, Yusuke Yamauchi

^*Corresponding author for this work

School of Medical and Technology

Research output: Contribution to journal › Article › peer-review

37 Citations (Scopus)

Abstract

An effective yet simple approach was developed to synthesize mesoporous PdBi nanocages for electrochemical applications. This technique relies on the subtle utilization of the hydrolysis of a metal salt to generate precipitate cores in situ as templates for navigating the growth of mesoporous shells with the assistance of polymeric micelles. The mesoporous PdBi nanocages are then obtained by excavating vulnerable cores and regulating the crystals of mesoporous metallic skeletons. The resultant mesoporous PdBi nanocages exhibited excellent electrocatalytic performance toward the ethanol oxidation reaction with a mass activity of 3.56 A mg⁻¹_Pd, specific activity of 17.82 mA cm⁻² and faradaic efficiency of up to 55.69% for C1 products.

Original language	English
Pages (from-to)	3819-3825
Number of pages	7
Journal	Chemical Science
Volume	13
Issue number	13
DOIs	https://doi.org/10.1039/d1sc06314f
Publication status	Published - 28 Feb 2022

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title = "Mesoporous PdBi nanocages for enhanced electrocatalytic performances by all-direction accessibility and steric site activation",

abstract = "An effective yet simple approach was developed to synthesize mesoporous PdBi nanocages for electrochemical applications. This technique relies on the subtle utilization of the hydrolysis of a metal salt to generate precipitate cores in situ as templates for navigating the growth of mesoporous shells with the assistance of polymeric micelles. The mesoporous PdBi nanocages are then obtained by excavating vulnerable cores and regulating the crystals of mesoporous metallic skeletons. The resultant mesoporous PdBi nanocages exhibited excellent electrocatalytic performance toward the ethanol oxidation reaction with a mass activity of 3.56 A mg−1_Pd, specific activity of 17.82 mA cm−2 and faradaic efficiency of up to 55.69% for C1 products.",

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T1 - Mesoporous PdBi nanocages for enhanced electrocatalytic performances by all-direction accessibility and steric site activation

AU - Du, Dawei

AU - Geng, Qinghong

AU - Ma, Lian

AU - Ren, Siyu

AU - Li, Jun Xuan

AU - Dong, Weikang

AU - Hua, Qingfeng

AU - Fan, Longlong

AU - Shao, Ruiwen

AU - Wang, Xiaoming

AU - Li, Cuiling

AU - Yamauchi, Yusuke

PY - 2022/2/28

Y1 - 2022/2/28

N2 - An effective yet simple approach was developed to synthesize mesoporous PdBi nanocages for electrochemical applications. This technique relies on the subtle utilization of the hydrolysis of a metal salt to generate precipitate cores in situ as templates for navigating the growth of mesoporous shells with the assistance of polymeric micelles. The mesoporous PdBi nanocages are then obtained by excavating vulnerable cores and regulating the crystals of mesoporous metallic skeletons. The resultant mesoporous PdBi nanocages exhibited excellent electrocatalytic performance toward the ethanol oxidation reaction with a mass activity of 3.56 A mg−1_Pd, specific activity of 17.82 mA cm−2 and faradaic efficiency of up to 55.69% for C1 products.

AB - An effective yet simple approach was developed to synthesize mesoporous PdBi nanocages for electrochemical applications. This technique relies on the subtle utilization of the hydrolysis of a metal salt to generate precipitate cores in situ as templates for navigating the growth of mesoporous shells with the assistance of polymeric micelles. The mesoporous PdBi nanocages are then obtained by excavating vulnerable cores and regulating the crystals of mesoporous metallic skeletons. The resultant mesoporous PdBi nanocages exhibited excellent electrocatalytic performance toward the ethanol oxidation reaction with a mass activity of 3.56 A mg−1_Pd, specific activity of 17.82 mA cm−2 and faradaic efficiency of up to 55.69% for C1 products.

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JO - Chemical Science

JF - Chemical Science

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ER -

Mesoporous PdBi nanocages for enhanced electrocatalytic performances by all-direction accessibility and steric site activation

Abstract

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