Moriau, Léonard Jean

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  • Moriau, Léonard Jean (1)
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Suppressing Platinum Electrocatalyst Degradation via a HighSurface-Area Organic Matrix Support

Smiljanić, Milutin Lj.; Bele, Marjan; Moriau, Léonard Jean; Vélez Santa, John Fredy; Menart, Svit; Šala, Martin; Hrnjić, Armin; Jovanovič, Primož; Ruiz-Zepeda, Francisco; Gaberšček, Miran; Hodnik, Nejc

(2021) 

TY  - JOUR
AU  - Smiljanić, Milutin Lj.
AU  - Bele, Marjan
AU  - Moriau, Léonard Jean
AU  - Vélez Santa, John Fredy
AU  - Menart, Svit
AU  - Šala, Martin
AU  - Hrnjić, Armin
AU  - Jovanovič, Primož
AU  - Ruiz-Zepeda, Francisco
AU  - Gaberšček, Miran
AU  - Hodnik, Nejc
PY  - 2021
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/10146
AB  - Degradation of carbon-supported Pt nanocatalysts in fuel cells and electrolyzers hinders widespread commercialization of these green technologies. Transition between oxidized and reduced states of Pt during fast potential spikes triggers significant Pt dissolution. Therefore, designing Pt-based catalysts able to withstand such conditions is of critical importance. We report here on a strategy to suppress Pt dissolution by using an organic matrix tris(aza)pentacene (TAP) as an alternative support material for Pt. The major benefit of TAP is its potential-dependent conductivity in aqueous media, which was directly evidenced by electrochemical impedance spectroscopy. At potentials below ∼0.45 VRHE, TAP is protonated and its conductivity is improved, which enables supported Pt to run hydrogen reactions. At potentials corresponding to Pt oxidation/reduction (>∼0.45 VRHE), TAP is deprotonated and its conductivity is restricted. Tunable conductivity of TAP enhanced the durability of the Pt/TAP with respect to Pt/C when these two materials were subjected to the same degradation protocol (0.1 M HClO4 electrolyte, 3000 voltammetric scans, 1 V/s, 0.05-1.4 VRHE). The exceptional stability of Pt/TAP composite on a nanoscale level was confirmed by identical location TEM imaging before and after the used degradation protocol. Suppression of transient Pt dissolution from Pt/TAP with respect to the Pt/C benchmark was directly measured in a setup consisting of an electrochemical flow cell connected to inductively coupled plasma-mass spectrometry.
T2  - ACS Omega
T1  - Suppressing Platinum Electrocatalyst Degradation via a HighSurface-Area Organic Matrix Support
VL  - 7
IS  - 4
SP  - 3540
EP  - 3548
DO  - 10.1021/acsomega.1c06028
ER  - 
@article{
author = "Smiljanić, Milutin Lj. and Bele, Marjan and Moriau, Léonard Jean and Vélez Santa, John Fredy and Menart, Svit and Šala, Martin and Hrnjić, Armin and Jovanovič, Primož and Ruiz-Zepeda, Francisco and Gaberšček, Miran and Hodnik, Nejc",
year = "2021",
abstract = "Degradation of carbon-supported Pt nanocatalysts in fuel cells and electrolyzers hinders widespread commercialization of these green technologies. Transition between oxidized and reduced states of Pt during fast potential spikes triggers significant Pt dissolution. Therefore, designing Pt-based catalysts able to withstand such conditions is of critical importance. We report here on a strategy to suppress Pt dissolution by using an organic matrix tris(aza)pentacene (TAP) as an alternative support material for Pt. The major benefit of TAP is its potential-dependent conductivity in aqueous media, which was directly evidenced by electrochemical impedance spectroscopy. At potentials below ∼0.45 VRHE, TAP is protonated and its conductivity is improved, which enables supported Pt to run hydrogen reactions. At potentials corresponding to Pt oxidation/reduction (>∼0.45 VRHE), TAP is deprotonated and its conductivity is restricted. Tunable conductivity of TAP enhanced the durability of the Pt/TAP with respect to Pt/C when these two materials were subjected to the same degradation protocol (0.1 M HClO4 electrolyte, 3000 voltammetric scans, 1 V/s, 0.05-1.4 VRHE). The exceptional stability of Pt/TAP composite on a nanoscale level was confirmed by identical location TEM imaging before and after the used degradation protocol. Suppression of transient Pt dissolution from Pt/TAP with respect to the Pt/C benchmark was directly measured in a setup consisting of an electrochemical flow cell connected to inductively coupled plasma-mass spectrometry.",
journal = "ACS Omega",
title = "Suppressing Platinum Electrocatalyst Degradation via a HighSurface-Area Organic Matrix Support",
volume = "7",
number = "4",
pages = "3540-3548",
doi = "10.1021/acsomega.1c06028"
}
Smiljanić, M. Lj., Bele, M., Moriau, L. J., Vélez Santa, J. F., Menart, S., Šala, M., Hrnjić, A., Jovanovič, P., Ruiz-Zepeda, F., Gaberšček, M.,& Hodnik, N.. (2021). Suppressing Platinum Electrocatalyst Degradation via a HighSurface-Area Organic Matrix Support. in ACS Omega, 7(4), 3540-3548.
https://doi.org/10.1021/acsomega.1c06028
Smiljanić ML, Bele M, Moriau LJ, Vélez Santa JF, Menart S, Šala M, Hrnjić A, Jovanovič P, Ruiz-Zepeda F, Gaberšček M, Hodnik N. Suppressing Platinum Electrocatalyst Degradation via a HighSurface-Area Organic Matrix Support. in ACS Omega. 2021;7(4):3540-3548.
doi:10.1021/acsomega.1c06028 .
Smiljanić, Milutin Lj., Bele, Marjan, Moriau, Léonard Jean, Vélez Santa, John Fredy, Menart, Svit, Šala, Martin, Hrnjić, Armin, Jovanovič, Primož, Ruiz-Zepeda, Francisco, Gaberšček, Miran, Hodnik, Nejc, "Suppressing Platinum Electrocatalyst Degradation via a HighSurface-Area Organic Matrix Support" in ACS Omega, 7, no. 4 (2021):3540-3548,
https://doi.org/10.1021/acsomega.1c06028 . .
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