AI Article Synopsis
- The carbon-coated silicon monoxide (SiO@C) is a leading candidate for high-capacity anodes in next-generation lithium-ion batteries, but faces challenges like low initial Coulombic efficiency (ICE) and significant volume expansion during use.
- A lithium and boron co-doping strategy was developed to improve ICE and reduce volume changes by creating lithium silicates to minimize active lithium loss and enhancing lithium diffusion within the anode material.
- The resulting Li/B co-doped SiO@C anodes demonstrated excellent performance with an ICE of 83.28%, 85.4% capacity retention after 200 cycles, and a composite with graphite achieving 90.1% ICE and impressive cycling stability after 250 cycles, making it a
Article Abstract
The carbon-coated silicon monoxide (SiO@C) has been considered as one of the most promising high-capacity anodes for the next-generation high-energy-density lithium-ion batteries (LIBs). However, the relatively low initial Coulombic efficiency (ICE) and the still existing huge volume expansion during repeated lithiation/delithiation cycling remain the greatest challenges to its practical application. Here, we developed a lithium and boron (Li/B) co-doping strategy to efficiently enhance the ICE and alleviate the volume expansion or pulverization of SiO@C anodes. The generated Li silicates (LiSiO) by Li doping will reduce the active Li loss during the initial cycling and enhance the ICE of SiO@C anodes. Meanwhile, B doping works to promote the Li diffusion and strengthen the internal bonding networks within SiO@C, enhancing its resistance to cracking and pulverization during cycling. As a result, the enhanced ICE (83.28%), suppressed volume expansion, and greatly improved cycling (85.4% capacity retention after 200 cycles) and rate performance could be achieved for the Li/B co-doped SiO@C (Li/B-SiO@C) anodes. Especially, the Li/B-SiO@C and graphite composite anodes with a capacity of 531.5 mA h g were demonstrated to show an ICE of 90.1% and superior cycling stability (90.1% capacity retention after 250 cycles), which is significant for the practical application of high-energy-density LIBs.
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| http://dx.doi.org/10.1021/acsami.2c04983 | DOI Listing |
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