Solid Oxide Based Electrolysis and Stack Technology with Ultra-High Electrolysis Current Density (>3A/cm2) and Efficiency | Zendy

Eric Tang | Zendy; Anthony Wood | Zendy; Casey Brown | Zendy; Micah Casteel | Zendy; Michael Pastula | Zendy; Mark Richards | Zendy; Randy Petri | Zendy

Open Access

Solid Oxide Based Electrolysis and Stack Technology with Ultra-High Electrolysis Current Density (>3A/cm<sup>2</sup>) and Efficiency

Author(s) -

Eric Tang,

Anthony Wood,

Casey Brown,

Micah Casteel,

Michael Pastula,

Mark Richards,

Randy Petri

Publication year - 2018

Publication title -

osti oai (u.s. department of energy office of scientific and technical information)

Language(s) - English

Resource type - Reports

DOI - 10.2172/1513461

Subject(s) - high temperature electrolysis , stack (abstract data type) , electrolysis , polymer electrolyte membrane electrolysis , high pressure electrolysis , current density , hydrogen production , materials science , hydrogen , nuclear engineering , process engineering , chemistry , electrode , computer science , engineering , physics , electrolyte , organic chemistry , quantum mechanics , programming language

• Coordinated this project with the stack design freeze and prototype repeatand non-repeat-part stack development from the DOE Office of Fossil Energy (FE) innovative project for the ultra-compact, low-cost stack design platform, called the compact solid oxide fuel cell (SOFC) architecture, thus enabling a single/common stack design platform that can operate in fuel cell systems in electrolysis systems, as well as in reversible SOFC systems for energy storage applications.

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