Recent Progress and Challenges in Mixed Ionic–Electronic Conducting Membranes for Oxygen Separation

Carbon neutrality refers to the state of making net‐zero emissions of carbon dioxide (CO2), which is a key concept in tackling global warming. It can be achieved by offsetting carbon emissions as well as balancing reduced and emitted emissions. Globally, CO2 is emitted mainly from fossil fuel power...

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Bibliographic Details
Published in:Advanced energy and sustainability research 2022-11, Vol.3 (11), p.n/a
Main Authors: Kwon, Young-il, Nam, Gyeong Duk, Lee, Gahyeon, Choi, Soomin, Joo, Jong Hoon
Format: Article
Language:English
Subjects:
active coating layers
bulk diffusions
Carbon dioxide
Carbon dioxide emissions
Carbon sequestration
Climate change
Combustion
Combustion products
Commercialization
dual-phase composites
Emissions
Energy efficiency
Flue gas
Fluorite
Fossil fuels
Fuel combustion
Global warming
High temperature
Mechanical properties
Membrane permeability
Membranes
Oxygen
oxygen surface exchanges
oxygen transport membranes
Permeability
Perovskites
Power plants
Sustainable use
Temperature
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Summary:Carbon neutrality refers to the state of making net‐zero emissions of carbon dioxide (CO2), which is a key concept in tackling global warming. It can be achieved by offsetting carbon emissions as well as balancing reduced and emitted emissions. Globally, CO2 is emitted mainly from fossil fuel power plants. The use of carbon capture and storage technology, including pre‐, post‐, and oxy‐fuel combustion capture, in power plants can provide a carbon‐neutral strategy that allows for the sustainable use of fossil fuels while potentially reducing CO2 emissions. Oxy‐fuel combustion capture facilitates CO2 capture by simplifying combustion products through the reaction of recirculated flue gas with a high‐purity oxygen. Oxygen transport membranes, which produce pure oxygen by oxygen transport via oxides at high temperatures, have attracted increased interest because they can improve overall efficiency when integrated with oxy‐fuel combustion capture. Dual‐phase membranes with fluorite structure have greater potential for commercialization than perovskite‐based single‐phase membranes, which have poor chemical and mechanical properties. However, despite these advantages, their low oxygen permeability remains a critical issue. This review focuses on progress in the development of dual‐phase membranes and summarizes various approaches that can facilitate bulk diffusion and surface exchange, which affect the oxygen permeability. This review focuses on progress in the development of dual‐phase membranes and summarizes various approaches that can facilitate bulk diffusion and surface exchange, which affect the oxygen permeability. Specifically, this review provides critical insight into intrinsic and extrinsic properties improving the performance of the dual‐phase membrane.
ISSN:2699-9412
2699-9412
DOI:10.1002/aesr.202200086