Protonic ceramic electrolysis cells | NREL HydroGEN

High performing triple-conductive Pr2NiO4+δ anode for proton-conducting steam solid oxide electrolysis cell

Submitted by nnguyen2 on Fri, 05/20/2022 - 16:41

Li W, Guan B, Ma L, Hu S, Zhang N, Liu X. 2018. High performing triple-conductive Pr2NiO4+δ anode for proton-conducting steam solid oxide electrolysis cell . Journal of Materials Chemistry A. 6:18057-18066.

Synergistic Coupling of Proton Conductors BaZr0.1Ce0.7Y0.1Yb0.1O3−δ and La2Ce2O7 to Create Chemical Stable, Interface Active Electrolyte for Steam Electrolysis Cells

Submitted by nnguyen2 on Fri, 05/20/2022 - 16:38

Li W, Guan B, Ma L, Tian H, Liu X. 2019. Synergistic Coupling of Proton Conductors BaZr0.1Ce0.7Y0.1Yb0.1O3−δ and La2Ce2O7 to Create Chemical Stable, Interface Active Electrolyte for Steam Electrolysis Cells. ACS Applied Materials & Interfaces. 11:18323-18330.

Ferritic stainless steel interconnects for protonic ceramic electrochemical cell stacks: Oxidation behavior and protective coatings

Submitted by nnguyen2 on Fri, 05/20/2022 - 16:03

Wang R, Sun Z, Choi J-P, Basu SN, Stevenson JW, Tucker MC. 2019. Ferritic stainless steel interconnects for protonic ceramic electrochemical cell stacks: Oxidation behavior and protective coatings. International Journal of Hydrogen Energy. 44:25297-25309.

Deconvolution of Water-Splitting on the Triple-Conducting Ruddlesden–Popper-Phase Anode for Protonic Ceramic Electrolysis Cells

Submitted by nnguyen2 on Fri, 05/13/2022 - 10:06

Tian H, Li W, Ma L, Yang T, Guan B, Shi W, Kalapos TL, Liu X. 2020. Deconvolution of Water-Splitting on the Triple-Conducting Ruddlesden–Popper-Phase Anode for Protonic Ceramic Electrolysis Cells. ACS Applied Materials & Interfaces. 12:49574-49585.

Revitalizing interface in protonic ceramic cells by acid etch

Submitted by nnguyen2 on Thu, 05/12/2022 - 09:34

Bian W, Wu W, Wang B, Tang W, Zhou M, Jin C, Ding H, Fan W, Dong Y, Li J et al.. 2022. Revitalizing interface in protonic ceramic cells by acid etch. Nature. 604:479-485.

Hydrogen Production: 3D Self-Architectured Steam Electrode Enabled Efficient and Durable Hydrogen Production in a Proton-Conducting Solid Oxide Electrolysis Cell at Temperatures Lower Than 600 °C (Adv. Sci. 11/2018)

Submitted by drupaladmin on Tue, 08/18/2020 - 14:10

Wu W, Ding H, Zhang Y, Ding Y, Katiyar P, Majumdar PK, He T, Ding D. 2018. Hydrogen Production: 3D Self-Architectured Steam Electrode Enabled Efficient and Durable Hydrogen Production in a Proton-Conducting Solid Oxide Electrolysis Cell at Temperatures Lower Than 600 °C (Adv. Sci. 11/2018). Advanced Science. 5(11):1870070.

Cobalt-substituted SrTi0.3Fe0.7O3−δ: a stable high-performance oxygen electrode material for intermediate-temperature solid oxide electrochemical cells

Submitted by drupaladmin on Tue, 08/18/2020 - 14:01

Zhang S-L, Wang H, Lu MY, Zhang A-P, Mogni LV, Liu Q, Li C-X, Li C-J, Barnett SA. 2018. Cobalt-substituted SrTi0.3Fe0.7O3−δ: a stable high-performance oxygen electrode material for intermediate-temperature solid oxide electrochemical cells. Energy & Environmental Science. 11(7):1870-1879.

Assessment of co-sintering as a fabrication approach for metal-supported proton-conducting solid oxide cells

Submitted by drupaladmin on Tue, 08/18/2020 - 13:42

Wang R, Byrne C, Tucker MC. 2019. Assessment of co-sintering as a fabrication approach for metal-supported proton-conducting solid oxide cells. Solid State Ionics. 332:25-33.

Approaches for co-sintering metal-supported proton-conducting solid oxide cells with Ba(Zr,Ce,Y,Yb)O3-δ electrolyte

Submitted by drupaladmin on Tue, 08/18/2020 - 13:08

Wang R, Lay GY, Ding D, Zhu T. 2019. Approaches for co-sintering metal-supported proton-conducting solid oxide cells with Ba(Zr,Ce,Y,Yb)O3-δ electrolyte. International Journal of Hydrogen Energy. 44(26):13768-13776.