AI Article Synopsis
- Researchers have developed advanced flexible batteries using free-standing graphene fiber electrodes made from roller-like oriented spore carbon spheres, which enhance energy density and mechanical strength for portable electronics.* -
- The innovative manufacturing process involves microfluidic cospinning and plasma reduction to create well-structured graphene fibers that improve electrical contact and stability.* -
- When paired with sulfur cathodes and lithium metal anodes, these graphene fiber-based batteries show outstanding electrochemical performance, suppressing common issues like polysulfide shuttle effects and lithium dendrite growth.*
Article Abstract
Flexible batteries with large energy densities, lightweight nature, and high mechanical strength are considered as an eager goal for portable electronics. Herein, we first propose free-standing graphene fiber electrodes containing roller-like orientated spore carbon spheres via rheological engineering. With the help of the orientated microfluidic cospinning technology and the plasma reduction method, spore carbon spheres are self-assembled and orientedly dispersed into numerous graphene flakes, forming graphene fiber electrodes enriched with internal rolling woven structures, which cannot only enhance the electrical contact between active materials but also effectively improve the mechanical strength and structure stability of graphene fiber electrodes. When the designed graphene fibers are combined with the active sulfur cathode and lithium metal anode, the assembled flexible lithium sulfur batteries possess superior electrochemical performance with high capacity (>1000 mA h g) and excellent cycling life as well as good mechanical properties. According to density functional theory and COMSOL simulations, the roller-like spore carbon sphere-orientated graphene fiber hosts provide reinforced trapping-catalytic-conversion behavior to soluble polysulfides and nucleation active sites to lithium metal, thus synergistically suppressing the shuttle effect of polysulfides at the cathode side and lithium dendrite growth at the anode side, thereby boosting the whole electrochemical properties of lithium sulfur batteries.
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| http://dx.doi.org/10.1021/acsnano.4c07864 | DOI Listing |
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