Numerical simulation of gas-diffusion-electrodes with moving gas-liquid interface: A study on pulse-current operation and electrode flooding. Schröder, D., Laue, V., & Krewer, U. Computers and Chemical Engineering, 84:217–225, January, 2016.
Numerical simulation of gas-diffusion-electrodes with moving gas-liquid interface: A study on pulse-current operation and electrode flooding [link]Paper  doi  abstract   bibtex   
In gas-diffusion-electrodes of electrochemical systems, the interface between gas and liquid electrolyte can move with operation time. It is challenging to mathematically assess moving interfaces, especially if the transient and spatial distribution of species are of interest. We mathematically model a gas-diffusion-electrode and apply a finite volume method with moving grid to solve the model equations. The step-size of the finite volume method is coupled to the moving gas-liquid interface, which is coupled to the current density applied. In detail, we study pulse-current operation and flooding of the electrode, and investigate parameters that influence the oxygen distribution in the electrode. The results obtained emphasize the benefit of the moving grid method applied. This method is able to assess the accurate diffusion resistance for oxygen in the gas-diffusion-electrode. Based on this work, possible limitations of gas-diffusion-electrodes can be derived for their usage in metal air batteries.
@article{schroder_numerical_2016,
	title = {Numerical simulation of gas-diffusion-electrodes with moving gas-liquid interface: {A} study on pulse-current operation and electrode flooding},
	volume = {84},
	copyright = {All rights reserved},
	issn = {00981354},
	url = {http://linkinghub.elsevier.com/retrieve/pii/S0098135415003002},
	doi = {10.1016/j.compchemeng.2015.09.005},
	abstract = {In gas-diffusion-electrodes of electrochemical systems, the interface between gas and liquid electrolyte can move with operation time. It is challenging to mathematically assess moving interfaces, especially if the transient and spatial distribution of species are of interest. We mathematically model a gas-diffusion-electrode and apply a finite volume method with moving grid to solve the model equations. The step-size of the finite volume method is coupled to the moving gas-liquid interface, which is coupled to the current density applied. In detail, we study pulse-current operation and flooding of the electrode, and investigate parameters that influence the oxygen distribution in the electrode. The results obtained emphasize the benefit of the moving grid method applied. This method is able to assess the accurate diffusion resistance for oxygen in the gas-diffusion-electrode. Based on this work, possible limitations of gas-diffusion-electrodes can be derived for their usage in metal air batteries.},
	journal = {Computers and Chemical Engineering},
	author = {Schröder, Daniel and Laue, Vincent and Krewer, Ulrike},
	month = jan,
	year = {2016},
	keywords = {Finite volume method, Gas-diffusion-electrode, Mathematical model, Metal air battery, Moving grid, Zinc air battery},
	pages = {217--225},
}
Downloads: 0
About
Documentation
Keywords
Search
Users
Terms and Conditions of Use
Privacy Policy
Sitemap
© BibBase.org 2021