High rate, high temperature, dendrite free plating/stripping of Li in 3-dimensional honeycomb boron carbon nitride to realize an ultrastable lithium metal anode

“…It is very difficult to obtain a 3D porous architecture having a ternary B−C−N morphology; however, these BCN systems have higher capability to replace currently available graphite anode materials in LIBs and hold higher capacity than graphite. 59 Most of the BCN materials reported in the literature are 1D tube or 2D graphene sheet-like structures. The performance of BCN can be improved by preparing a 3D porous structure because 3D porous structures have efficient properties for LIBs, such as higher pore volume for improving Li intake capability, higher surface area for providing efficient electrode−electrolyte contact, and tunability in pore size to facilitate fast charge transfer and ample reduction to the polarization effect.…”

“…3D BCN, having a porous morphology and carbonaceous architecture, has limited reports in the literature. It is very difficult to obtain a 3D porous architecture having a ternary B–C–N morphology; however, these BCN systems have higher capability to replace currently available graphite anode materials in LIBs and hold higher capacity than graphite . Most of the BCN materials reported in the literature are 1D tube or 2D graphene sheet-like structures.…”

Boron Carbon Nitride (BCN): An Emerging Two-Dimensional Material for Rechargeable Batteries

“…It is very difficult to obtain a 3D porous architecture having a ternary B−C−N morphology; however, these BCN systems have higher capability to replace currently available graphite anode materials in LIBs and hold higher capacity than graphite. 59 Most of the BCN materials reported in the literature are 1D tube or 2D graphene sheet-like structures. The performance of BCN can be improved by preparing a 3D porous structure because 3D porous structures have efficient properties for LIBs, such as higher pore volume for improving Li intake capability, higher surface area for providing efficient electrode−electrolyte contact, and tunability in pore size to facilitate fast charge transfer and ample reduction to the polarization effect.…”

“…3D BCN, having a porous morphology and carbonaceous architecture, has limited reports in the literature. It is very difficult to obtain a 3D porous architecture having a ternary B–C–N morphology; however, these BCN systems have higher capability to replace currently available graphite anode materials in LIBs and hold higher capacity than graphite . Most of the BCN materials reported in the literature are 1D tube or 2D graphene sheet-like structures.…”

Boron Carbon Nitride (BCN): An Emerging Two-Dimensional Material for Rechargeable Batteries

“…However, traditional anode materials, like graphite, are hampered by a specific capacity limit of 372 mAh g −1 , rendering them inadequate for future demands. 5,6 Consequently, there is an increasing need for LIBs with high energy and power densities coupled with rapid charging capabilities. 7−9 Addressing these demands poses challenges, given the limitations of conventional materials, which face increased charge transfer constraints as well as resistance in thicker electrodes.…”

“…Since their emergence in the 1990s, lithium-ion batteries (LIBs) have garnered significant attention, becoming indispensable power sources in electric vehicles and portable electronics. − Among the components of LIBs, the anode plays a critical role in dictating electrochemical performance. However, traditional anode materials, like graphite, are hampered by a specific capacity limit of 372 mAh g –1 , rendering them inadequate for future demands. , Consequently, there is an increasing need for LIBs with high energy and power densities coupled with rapid charging capabilities. − Addressing these demands poses challenges, given the limitations of conventional materials, which face increased charge transfer constraints as well as resistance in thicker electrodes . To tackle this, a common strategy involves the integration of high-capacity materials to reduce electrode size.…”

N-Doped Hollow Multichannel Carbon Nanofibers Encased in Fe₃C for Lithium-Ion Storage

An ultrathin and robust single-ion conducting interfacial layer for dendrite-free lithium metal batteries