An Unbalanced Battle in Excellence: Revealing Effect of Ni/Co Occupancy on Water Splitting and Oxygen Reduction Reactions in Triple-Conducting Oxides for Protonic Ceramic Electrochemical Cells.
Wei TangHanping DingWenjuan BianClarita Y Regalado VeraJoshua Y GomezYanhao DongJu LiWei WuWeiWei FanMeng ZhouColin GoreBryan M BlackburnHongmei LuoDong DingPublished in: Small (Weinheim an der Bergstrasse, Germany) (2022)
Porous electrodes that conduct electrons, protons, and oxygen ions with dramatically expanded catalytic active sites can replace conventional electrodes with sluggish kinetics in protonic ceramic electrochemical cells. In this work, a strategy is utilized to promote triple conduction by facilitating proton conduction in praseodymium cobaltite perovskite through engineering non-equivalent B-site Ni/Co occupancy. Surface infrared spectroscopy is used to study the dehydration behavior, which proves the existence of protons in the perovskite lattice. The proton mobility and proton stability are investigated by hydrogen/deuterium (H/D) isotope exchange and temperature-programmed desorption. It is observed that the increased nickel replacement on the B-site has a positive impact on proton defect stability, catalytic activity, and electrochemical performance. This doping strategy is demonstrated to be a promising pathway to increase catalytic activity toward the oxygen reduction and water splitting reactions. The chosen PrNi 0.7 Co 0.3 O 3- δ oxygen electrode demonstrates excellent full-cell performance with high electrolysis current density of -1.48 A cm -2 at 1.3 V and a peak fuel-cell power density of 0.95 W cm -2 at 600 °C and also enables lower-temperature operations down to 350 °C, and superior long-term durability.
Keyphrases
- induced apoptosis
- gold nanoparticles
- electron transfer
- cell cycle arrest
- single cell
- ionic liquid
- carbon nanotubes
- cell therapy
- reduced graphene oxide
- metal organic framework
- molecularly imprinted
- room temperature
- endoplasmic reticulum stress
- cell death
- stem cells
- high efficiency
- signaling pathway
- solid state
- cell proliferation
- aqueous solution
- gas chromatography
- high speed