Gas diffusion, transport characteristics and modelling in porous membrane systems with application for polymer electrolyte membrane fuel cells.

Aisueni, Florence; Ramalan, Muktar; Abunumah, Ofasa; Ogunlude, Priscilla; Orakwe, Ifeyinwa; Ogoun, Evans; Giwa, Ayo; Shehu, Habiba; Gobina, Edward

Gas diffusion, transport characteristics and modelling in porous membrane systems with application for polymer electrolyte membrane fuel cells.

Aisueni, Florence; Ramalan, Muktar; Abunumah, Ofasa; Ogunlude, Priscilla; Orakwe, Ifeyinwa; Ogoun, Evans; Giwa, Ayo; Shehu, Habiba; Gobina, Edward

Authors

FLORENCE AISUENI f.a.aisueni@rgu.ac.uk
Research Student

MUKTAR RAMALAN m.ramalan@rgu.ac.uk
Research Student

Ofasa Abunumah

Priscilla Ogunlude

Ifeyinwa Orakwe

EVANS OGOUN e.ogoun@rgu.ac.uk
Research Student

Ayo Giwa

Habiba Shehu

Edward Gobina

Abstract

Fuel cells convert chemical energy in electrical energy and heat by consuming typically hydrogen and oxygen and producing water as the main by-product. This is achieved by reducing hydrogen at the anode (left hand side) and oxidising oxygen at the cathode (right hand side). The polymer electrolyte membrane fuel cell (PEMFC) gas diffusion layer (GDL) and the catalyst layer (CL) are crucial components mainly responsible for the distribution of gases, chemical reaction, and water transport in any PEMFC. The GDL consists of two main layers which are the macroporous substrate (MPS) and microporous layer (MPL). The MPS comes before the gas flow field and provides gas diffusion through a carbon-based paper or carbon cloth and collects the current. MPL is generally used to reduce the contact resistance between the CL and GDL. The most important parameters of porous membranes are derived from Fick's first law which relates the molar flux to membrane permeability. All possible gas transport mechanisms in porous membrane have been investigated in literature such as Hagen-Pouiselle, Knudsen, surface diffusion, capillary condensation, and molecular sieving.

Citation

AISUENI, F., RAMALAN, M., ABUNUMAH, O., OGUNLUDE, P., ORAKWE, I., OGOUN, E., GIWA, A., SHEHU, H. and GOBINA, E. 2022. Gas diffusion, transport characteristics and modelling in porous membrane systems with application for polymer electrolyte membrane fuel cells. In Proceedings of the 2nd International congress on scientific advances 2022 (ICONSAD'22), 21-24 December 2022, [virtual conference]. Turkey: ICONSAD [online], pages 144-157. Available from: https://en.iconsad.org/_files/ugd/1dd905_c45aeddf416d497e93113f00f465739b.pdf

Conference Name	2nd International congress on scientific advances 2022 (ICONSAD'22)
Conference Location	[virtual conference]
Start Date	Dec 21, 2022
End Date	Dec 24, 2022
Acceptance Date	Dec 7, 2022
Online Publication Date	Dec 9, 2022
Publication Date	Jan 6, 2023
Deposit Date	Jan 18, 2023
Publicly Available Date	Feb 21, 2023
Publisher	ICONSAD (International congress on scientific advances)
Book Title	Proceedings of the 2nd International congress on scientific advances 2022 (ICONSAD'22)
ISBN	9786057363954
Keywords	Polymer electrolyte; Fuel cells; Membrane; Gas diffusion layer; Catalyst layer; Knudsen number; Mean free path
Public URL	https://rgu-repository.worktribe.com/output/1848657
Publisher URL	https://en.iconsad.org/_files/ugd/1dd905_c45aeddf416d497e93113f00f465739b.pdf