AI Article Synopsis
- WS nanoflakes could be really good for making better batteries, like lithium-ion and sodium-ion batteries, because of their special 2D shape that helps move metal ions in and out.
- Scientists are studying how these nanoflakes work on a tiny level to see how well they hold and release energy during battery charging and discharging.
- They found that sodium-ion batteries can store more energy and last longer compared to lithium-ion batteries, and the changes in the nanoflakes' structure when they process sodium are less dramatic than with lithium.
Article Abstract
WS nanoflakes have great potential as electrode materials of lithium-ion batteries (LIBs) and sodium-ion batteries (SIBs) because of their unique 2D structure, which facilitates the reversible intercalation and extraction of alkali metal ions. However, a fundamental understanding of the electrochemical lithiation/sodiation dynamics of WS nanoflakes especially at the nanoscale level, remains elusive. Here, by combining battery electrochemical measurements, density functional theory calculations, and in situ transmission electron microscopy, the electrochemical-reaction kinetics and mechanism for both lithiation and sodiation of WS nanoflakes are investigated at the atomic scale. It is found that compared to LIBs, SIBs exhibit a higher reversible sodium (Na) storage capacity and superior cyclability. For sodiation, the volume change due to ion intercalation is smaller than that in lithiation. Also, sodiated WS maintains its layered structure after the intercalation process, and the reduced metal nanoparticles after conversion in sodiation are well-dispersed and aligned forming a pattern similar to the layered structure. Overall, this work shows a direct interconnection between the reaction dynamics of lithiated/sodiated WS nanoflakes and their electrochemical performance, which sheds light on the rational optimization and development of advanced WS -based electrodes.
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| http://dx.doi.org/10.1002/smll.202100637 | DOI Listing |
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