Na metal anodes for liquid and solid-state Na batteries

Literature Information

Publication Date 2023-11-16
DOI 10.1039/D3EE03477A
Impact Factor 38.532
Authors

Parham Pirayesh, Enzhong Jin, Yijia Wang, Yang Zhao


View Original

Abstract

Because of the high abundance, cost-effectiveness and low redox potential of Na, rechargeable Na metal batteries (NMBs) are considered an ideal alternative and complementary to state-of-the-art lithium-ion batteries. Despite numerous research efforts that have been made to accelerate the development of the NMBs utilizing both liquid- and solid-state electrolytes, issues such as Na dendrite formation, undesirable side reactions, and infinite volume changes remain to be addressed. This review paper presents a thorough examination of the progress and accomplishments of liquid-based and solid-state NMBs. It encompasses a comprehensive analysis of fundamental studies and practical applications, an extensive comparison between Li and Na metal anodes, along with an in-depth discussion of the fundamentals of Na dendrite formation in both liquid- and solid-state electrolytes. Furthermore, we summarize various promising approaches for addressing the associated issues and challenges. Through our review, we aim to accelerate the progress in comprehending and utilizing Na metal anodes for practical NMB systems.

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Source Journal

Energy & Environmental Science

Energy & Environmental Science
CiteScore: 32.34
Self-citation Rate: 3.4%
Articles per Year: 481

Energy & Environmental Science is an international journal dedicated to publishing exceptionally important and high quality, agenda-setting research tackling the key global and societal challenges of ensuring the provision of energy and protecting our environment for the future. The scope is intentionally broad and the journal recognises the complexity of issues and challenges relating to energy conversion and storage, alternative fuel technologies and environmental science. For work to be published it must be linked to the energy-environment nexus and be of significant general interest to our community-spanning readership. All scales of studies and analysis, from impactful fundamental advances, to interdisciplinary research across the (bio)chemical, (bio/geo)physical sciences and chemical engineering disciplines are welcomed. Topics include, but are not limited to, the following: Solar energy conversion and photovoltaics Solar fuels and artificial photosynthesis Fuel cells Hydrogen storage and (bio) hydrogen production Materials for energy systems Capture, storage and fate of CO2, including chemicals and fuels from CO2 Catalysis for a variety of feedstocks (for example, oil, gas, coal, biomass and synthesis gas) Biofuels and biorefineries Materials in extreme environments Environmental impacts of energy technologies Global atmospheric chemistry and climate change as related to energy systems Water-energy nexus Energy systems and networks Globally applicable principles of energy policy and techno-economics

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