Modeling of Pore-Scale Capillary-Dominated Flow and Bubble Detachment in PEM Water Electrolyzer Anodes Using the Volume of Fluid Method

Gergely Schmidt; Daniel Niblett; Vahid Niasar; Insa Neuweiler

doi:10.1149/1945-7111/ad5708

Details

Originalsprache	Englisch
Aufsatznummer	074503
Seitenumfang	16
Fachzeitschrift	Journal of the Electrochemical Society
Jahrgang	171
Ausgabenummer	7
Publikationsstatus	Veröffentlicht - 3 Juli 2024

Abstract

Fluid dynamics models complement expensive experiments with limited measurement accuracy that investigate the mass transport in PEM water electrolysis. Here, a first-principle microscale model for oxygen transport is successfully validated that accounts for (1) uncertain transport processes in catalyst layers, (2) numerically challenging capillary-dominated two-phase flow and (3) bubble detachments in channels. We developed algorithms for the stochastic generation of geometries and for the coupling of flow and transport processes. The flow model is based on the volume of fluid method and reproduces experimentally measured pressure drops and bubble velocities within minichannels with a 30% and 20% accuracy, respectively, provided that the capillary number is above 2.1 × 10⁻⁷. At lower capillary numbers, excessive spurious currents occur. Correspondingly, two-phase flow simulations within the porous transport layers are stable at current densities above 0.5 A cm⁻² and match operando gas saturation measurements within a 20% margin at relevant locations. The simulated bubble detachments occur at pore throats that agree with porosimetry and microfluidic experiments. The presented model allows explaining and optimizing mass transport processes in channels and porous transport layers. These were found to be negligibly sensitive to transport resistances within the catalyst layer, providing information on boundary conditions for future catalyst layer models.

ASJC Scopus Sachgebiete

Werkstoffwissenschaften (insg.)
Elektronische, optische und magnetische Materialien
Energie (insg.)
Erneuerbare Energien, Nachhaltigkeit und Umwelt
Physik und Astronomie (insg.)
Physik der kondensierten Materie
Werkstoffwissenschaften (insg.)
Oberflächen, Beschichtungen und Folien
Chemie (insg.)
Elektrochemie
Werkstoffwissenschaften (insg.)
Werkstoffchemie

Ziele für nachhaltige Entwicklung

SDG 7 – Erschwingliche und saubere Energie

Zitieren

Modeling of Pore-Scale Capillary-Dominated Flow and Bubble Detachment in PEM Water Electrolyzer Anodes Using the Volume of Fluid Method. / Schmidt, Gergely; Niblett, Daniel; Niasar, Vahid et al.
in: Journal of the Electrochemical Society, Jahrgang 171, Nr. 7, 074503, 03.07.2024.

Publikation: Beitrag in Fachzeitschrift › Artikel › Forschung › Peer-Review

Schmidt, G, Niblett, D, Niasar, V & Neuweiler, I 2024, 'Modeling of Pore-Scale Capillary-Dominated Flow and Bubble Detachment in PEM Water Electrolyzer Anodes Using the Volume of Fluid Method', Journal of the Electrochemical Society, Jg. 171, Nr. 7, 074503. https://doi.org/10.1149/1945-7111/ad5708

Schmidt, G., Niblett, D., Niasar, V., & Neuweiler, I. (2024). Modeling of Pore-Scale Capillary-Dominated Flow and Bubble Detachment in PEM Water Electrolyzer Anodes Using the Volume of Fluid Method. Journal of the Electrochemical Society, 171(7), Artikel 074503. https://doi.org/10.1149/1945-7111/ad5708

Schmidt G, Niblett D, Niasar V, Neuweiler I. Modeling of Pore-Scale Capillary-Dominated Flow and Bubble Detachment in PEM Water Electrolyzer Anodes Using the Volume of Fluid Method. Journal of the Electrochemical Society. 2024 Jul 3;171(7):074503. doi: 10.1149/1945-7111/ad5708

Schmidt, Gergely ; Niblett, Daniel ; Niasar, Vahid et al. / Modeling of Pore-Scale Capillary-Dominated Flow and Bubble Detachment in PEM Water Electrolyzer Anodes Using the Volume of Fluid Method. in: Journal of the Electrochemical Society. 2024 ; Jahrgang 171, Nr. 7.

Download

@article{b4b55de20ee64b809fcc1503978ed297,

title = "Modeling of Pore-Scale Capillary-Dominated Flow and Bubble Detachment in PEM Water Electrolyzer Anodes Using the Volume of Fluid Method",

abstract = "Fluid dynamics models complement expensive experiments with limited measurement accuracy that investigate the mass transport in PEM water electrolysis. Here, a first-principle microscale model for oxygen transport is successfully validated that accounts for (1) uncertain transport processes in catalyst layers, (2) numerically challenging capillary-dominated two-phase flow and (3) bubble detachments in channels. We developed algorithms for the stochastic generation of geometries and for the coupling of flow and transport processes. The flow model is based on the volume of fluid method and reproduces experimentally measured pressure drops and bubble velocities within minichannels with a 30% and 20% accuracy, respectively, provided that the capillary number is above 2.1 × 10−7. At lower capillary numbers, excessive spurious currents occur. Correspondingly, two-phase flow simulations within the porous transport layers are stable at current densities above 0.5 A cm−2 and match operando gas saturation measurements within a 20% margin at relevant locations. The simulated bubble detachments occur at pore throats that agree with porosimetry and microfluidic experiments. The presented model allows explaining and optimizing mass transport processes in channels and porous transport layers. These were found to be negligibly sensitive to transport resistances within the catalyst layer, providing information on boundary conditions for future catalyst layer models.",

keywords = "bubble dynamics, capillary-dominated displacement, mass transport, multiphase flow, water electrolysis",

author = "Gergely Schmidt and Daniel Niblett and Vahid Niasar and Insa Neuweiler",

note = "Publisher Copyright: {\textcopyright} 2024 The Author(s). Published on behalf of The Electrochemical Society by IOP Publishing Limited",

year = "2024",

month = jul,

day = "3",

doi = "10.1149/1945-7111/ad5708",

language = "English",

volume = "171",

journal = "Journal of the Electrochemical Society",

issn = "0013-4651",

publisher = "Electrochemical Society, Inc.",

number = "7",

}

Download

TY - JOUR

T1 - Modeling of Pore-Scale Capillary-Dominated Flow and Bubble Detachment in PEM Water Electrolyzer Anodes Using the Volume of Fluid Method

AU - Schmidt, Gergely

AU - Niblett, Daniel

AU - Niasar, Vahid

AU - Neuweiler, Insa

PY - 2024/7/3

Y1 - 2024/7/3

N2 - Fluid dynamics models complement expensive experiments with limited measurement accuracy that investigate the mass transport in PEM water electrolysis. Here, a first-principle microscale model for oxygen transport is successfully validated that accounts for (1) uncertain transport processes in catalyst layers, (2) numerically challenging capillary-dominated two-phase flow and (3) bubble detachments in channels. We developed algorithms for the stochastic generation of geometries and for the coupling of flow and transport processes. The flow model is based on the volume of fluid method and reproduces experimentally measured pressure drops and bubble velocities within minichannels with a 30% and 20% accuracy, respectively, provided that the capillary number is above 2.1 × 10−7. At lower capillary numbers, excessive spurious currents occur. Correspondingly, two-phase flow simulations within the porous transport layers are stable at current densities above 0.5 A cm−2 and match operando gas saturation measurements within a 20% margin at relevant locations. The simulated bubble detachments occur at pore throats that agree with porosimetry and microfluidic experiments. The presented model allows explaining and optimizing mass transport processes in channels and porous transport layers. These were found to be negligibly sensitive to transport resistances within the catalyst layer, providing information on boundary conditions for future catalyst layer models.

AB - Fluid dynamics models complement expensive experiments with limited measurement accuracy that investigate the mass transport in PEM water electrolysis. Here, a first-principle microscale model for oxygen transport is successfully validated that accounts for (1) uncertain transport processes in catalyst layers, (2) numerically challenging capillary-dominated two-phase flow and (3) bubble detachments in channels. We developed algorithms for the stochastic generation of geometries and for the coupling of flow and transport processes. The flow model is based on the volume of fluid method and reproduces experimentally measured pressure drops and bubble velocities within minichannels with a 30% and 20% accuracy, respectively, provided that the capillary number is above 2.1 × 10−7. At lower capillary numbers, excessive spurious currents occur. Correspondingly, two-phase flow simulations within the porous transport layers are stable at current densities above 0.5 A cm−2 and match operando gas saturation measurements within a 20% margin at relevant locations. The simulated bubble detachments occur at pore throats that agree with porosimetry and microfluidic experiments. The presented model allows explaining and optimizing mass transport processes in channels and porous transport layers. These were found to be negligibly sensitive to transport resistances within the catalyst layer, providing information on boundary conditions for future catalyst layer models.

KW - bubble dynamics

KW - capillary-dominated displacement

KW - mass transport

KW - multiphase flow

KW - water electrolysis

UR - http://www.scopus.com/inward/record.url?scp=85198023987&partnerID=8YFLogxK

U2 - 10.1149/1945-7111/ad5708

DO - 10.1149/1945-7111/ad5708

M3 - Article

AN - SCOPUS:85198023987

VL - 171

JO - Journal of the Electrochemical Society

JF - Journal of the Electrochemical Society

SN - 0013-4651

IS - 7

M1 - 074503

ER -

Research@Leibniz University

Modeling of Pore-Scale Capillary-Dominated Flow and Bubble Detachment in PEM Water Electrolyzer Anodes Using the Volume of Fluid Method

Autoren

Organisationseinheiten

Externe Organisationen

Details

Abstract

ASJC Scopus Sachgebiete

Ziele für nachhaltige Entwicklung

Zitieren