Your search keyword '"Oxygen production"' showing total 2 results

1. Ultra‐High Temperature Molten Oxide Electrochemistry.

Author

Wang, Mingyong, Jiao, Handong, Pu, Zhenghao, Hong, Biao, Ge, Jianbang, Xiao, Wei, and Jiao, Shuqiang

Subjects

*LUNAR soil, *ELECTROCHEMISTRY, *OXYGEN evolution reactions, *LIQUID metals, *IN situ processing (Mining)

Abstract

Recently, the ultra‐high temperature electrochemistry (UTE, about >1000 °C) has emerged, which represents an exploration to extend the temperature limit of human technology in electrochemical engineering. UTE has far‐reaching impact on revolutionary low‐carbon metal extraction and the in situ production of oxygen for deep‐space exploration. It is hence of urgency to systematically summarize the development of UTE. In this Review, the basic concepts of UTE and the physicochemical properties of molten oxides are analyzed. The principles in the design of inert anodes for the oxygen evolution reaction in molten oxides are discussed, which forms a solid basis for the in situ production of oxygen from simulated lunar regolith by UTE. Furthermore, liquid metal cathodes for revolutionary titanium extraction and ironmaking/steelmaking are highlighted. With emphasis on the key challenges and perspectives, the Review can provide valuable inspiration for the rapid advancement of UTE. [ABSTRACT FROM AUTHOR]

Published

2022

2. Water Oxidation with Cobalt‐Loaded Linear Conjugated Polymer Photocatalysts.

Author

Sprick, Reiner Sebastian, Chen, Zheng, Cowan, Alexander J., Bai, Yang, Aitchison, Catherine M., Fang, Yuanxing, Zwijnenburg, Martijn A., Cooper, Andrew I., and Wang, Xinchen

Subjects

*LINEAR polymers, *OXIDATION of water, *LIGHT absorption, *OXYGEN in water, *CONJUGATED polymers, *POLYMERS

Abstract

The first examples of linear conjugated organic polymer photocatalysts that produce oxygen from water after loading with cobalt and in the presence of an electron scavenger are reported. The oxygen evolution rates, which are higher than for related organic materials, can be rationalized by a combination of the thermodynamic driving force for water oxidation, the light absorption of the polymer, and the aqueous dispersibility of the relatively hydrophilic polymer particles. We also used transient absorption spectroscopy to study the best performing system and we found that fast oxidative quenching of the exciton occurs (picoseconds) in the presence of an electron scavenger, minimizing recombination. [ABSTRACT FROM AUTHOR]

Published

2020