Enhanced Adhesion of Continuous Nanoporous Au Layers by Thermochemical Oxidation of Glassy Carbon

Enhanced Adhesion of Continuous Nanoporous Au Layers by Thermochemical Oxidation of Glassy Carbon

The fabrication of a nanoporous gold (NPG)-based catalyst on a glassy carbon (GC) support results normally in large isolated and poorly adhering clusters that suffer considerable material loss upon durability testing. This work exploits thermochemical oxidation of GC, which, coupled with the utiliza...

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Main Authors: Lori Ana Bromberg, Jiaxin Xia, Ryan Rooney, Nikolay Dimitrov
Format: Article
Language:English
Published: MDPI AG 2014-07-01
Series:Coatings
Subjects:
adhesion
glassy carbon
thermochemical oxidation
nanoporous Au
catalyst
Online Access:http://www.mdpi.com/2079-6412/4/3/416
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spelling doaj-a813831226304ff1ba8a739f93cb0dd22020-11-24T22:42:25ZengMDPI AGCoatings2079-64122014-07-014341643210.3390/coatings4030416coatings4030416Enhanced Adhesion of Continuous Nanoporous Au Layers by Thermochemical Oxidation of Glassy CarbonLori Ana Bromberg0Jiaxin Xia1Ryan Rooney2Nikolay Dimitrov3Department of Chemistry, Binghamton University, PO Box 6000, Binghamton, NY 13902-6000, USADepartment of Chemistry, Binghamton University, PO Box 6000, Binghamton, NY 13902-6000, USADepartment of Chemistry, Binghamton University, PO Box 6000, Binghamton, NY 13902-6000, USADepartment of Chemistry, Binghamton University, PO Box 6000, Binghamton, NY 13902-6000, USAThe fabrication of a nanoporous gold (NPG)-based catalyst on a glassy carbon (GC) support results normally in large isolated and poorly adhering clusters that suffer considerable material loss upon durability testing. This work exploits thermochemical oxidation of GC, which, coupled with the utilization of some recent progress in fabricating continuous NPG layers using a Pd seed layer, aims to enhance the adhesion to the GC surface. Thermochemical oxidation causes interconnected pores within the GC structure to open and substantially improves the wettability of the GC surface, which are both beneficial toward the improvement of the overall quality of the NPG deposit. It is demonstrated that thermochemical oxidation neither affects the efficiency of the Au0.3Ag0.7 alloy (NPG precursor) deposition nor hinders the achievement of continuity in the course of the NPG fabrication process. Furthermore, adhesion tests performed by a rotating disk electrode setup on deposits supported on thermochemically-oxidized and untreated GCs ascertain the enhanced adhesion on the thermochemically-oxidized samples. The best adhesion results are obtained on a continuous NPG layer fabricated on thermochemically-oxidized GC electrodes seeded with a dense network of Pd clusters.http://www.mdpi.com/2079-6412/4/3/416adhesionglassy carbonthermochemical oxidationnanoporous Aucatalyst
collection DOAJ
language English
format Article
sources DOAJ
author Lori Ana Bromberg
Jiaxin Xia
Ryan Rooney
Nikolay Dimitrov
spellingShingle Lori Ana Bromberg
Jiaxin Xia
Ryan Rooney
Nikolay Dimitrov
Enhanced Adhesion of Continuous Nanoporous Au Layers by Thermochemical Oxidation of Glassy Carbon
Coatings
adhesion
glassy carbon
thermochemical oxidation
nanoporous Au
catalyst
author_facet Lori Ana Bromberg
Jiaxin Xia
Ryan Rooney
Nikolay Dimitrov
author_sort Lori Ana Bromberg
title Enhanced Adhesion of Continuous Nanoporous Au Layers by Thermochemical Oxidation of Glassy Carbon
title_short Enhanced Adhesion of Continuous Nanoporous Au Layers by Thermochemical Oxidation of Glassy Carbon
title_full Enhanced Adhesion of Continuous Nanoporous Au Layers by Thermochemical Oxidation of Glassy Carbon
title_fullStr Enhanced Adhesion of Continuous Nanoporous Au Layers by Thermochemical Oxidation of Glassy Carbon
title_full_unstemmed Enhanced Adhesion of Continuous Nanoporous Au Layers by Thermochemical Oxidation of Glassy Carbon
title_sort enhanced adhesion of continuous nanoporous au layers by thermochemical oxidation of glassy carbon
publisher MDPI AG
series Coatings
issn 2079-6412
publishDate 2014-07-01
description The fabrication of a nanoporous gold (NPG)-based catalyst on a glassy carbon (GC) support results normally in large isolated and poorly adhering clusters that suffer considerable material loss upon durability testing. This work exploits thermochemical oxidation of GC, which, coupled with the utilization of some recent progress in fabricating continuous NPG layers using a Pd seed layer, aims to enhance the adhesion to the GC surface. Thermochemical oxidation causes interconnected pores within the GC structure to open and substantially improves the wettability of the GC surface, which are both beneficial toward the improvement of the overall quality of the NPG deposit. It is demonstrated that thermochemical oxidation neither affects the efficiency of the Au0.3Ag0.7 alloy (NPG precursor) deposition nor hinders the achievement of continuity in the course of the NPG fabrication process. Furthermore, adhesion tests performed by a rotating disk electrode setup on deposits supported on thermochemically-oxidized and untreated GCs ascertain the enhanced adhesion on the thermochemically-oxidized samples. The best adhesion results are obtained on a continuous NPG layer fabricated on thermochemically-oxidized GC electrodes seeded with a dense network of Pd clusters.
topic adhesion
glassy carbon
thermochemical oxidation
nanoporous Au
catalyst
url http://www.mdpi.com/2079-6412/4/3/416
work_keys_str_mv AT lorianabromberg enhancedadhesionofcontinuousnanoporousaulayersbythermochemicaloxidationofglassycarbon
AT jiaxinxia enhancedadhesionofcontinuousnanoporousaulayersbythermochemicaloxidationofglassycarbon
AT ryanrooney enhancedadhesionofcontinuousnanoporousaulayersbythermochemicaloxidationofglassycarbon
AT nikolaydimitrov enhancedadhesionofcontinuousnanoporousaulayersbythermochemicaloxidationofglassycarbon
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