Probing C3N/Graphene heterostructures as anode materials for Li-ion batteries

“…1,2 Among different energy storage systems, lithium-ion batteries (LIBs) as the most prominent representative of secondary batteries, have been widely commercialized due to their signicant advantages of large energy density, long circle-life and high performance. [3][4][5] However, the further development of LIBs is impeded by cost and safety issues, and limited natural reserves and geometric consumption will result in lithium resources being in short supply. Therefore, non-Li ion batteries in which other metal ions replace the Li ions are receiving great attention.…”

Exploring the potentials of Ti₃N₂ and Ti₃N₂X₂ (X = O, F, OH) monolayers as anodes for Li or non-Li ion batteries from first-principles calculations

“…1,2 Among different energy storage systems, lithium-ion batteries (LIBs) as the most prominent representative of secondary batteries, have been widely commercialized due to their signicant advantages of large energy density, long circle-life and high performance. [3][4][5] However, the further development of LIBs is impeded by cost and safety issues, and limited natural reserves and geometric consumption will result in lithium resources being in short supply. Therefore, non-Li ion batteries in which other metal ions replace the Li ions are receiving great attention.…”

Exploring the potentials of Ti₃N₂ and Ti₃N₂X₂ (X = O, F, OH) monolayers as anodes for Li or non-Li ion batteries from first-principles calculations

“…The heterostructure recorded a high theoretical capacity of 1079 mAh g −1 , a low Li diffusion barrier of 0.28 eV at the interlayer (Fig. 9a), and operated at a low open-circuit voltage of 0.13 V [37]. Ding et al reported the first-principle study of C 2 N/graphene bilayer for LIBs, and by using molecular dynamic (MD) simulations, they predicted that Li storage follows a two-step process, i.e., migration through the z-direction via the large hole in the center of the C 2 N black blended g-C 3 N 4 (g-C-coated) for Li-S battery and showed that two bonds (C-S and N-Li) are formed as a result of its interaction with LIPSs.…”

“…Carbon atoms from graphene-gray balls, carbon atoms from C 3 N-orange balls, nitrogen atoms-blue and lithium atoms-green. Reproduced with permission from Ref [37]…”

DFT-Guided Design and Fabrication of Carbon-Nitride-Based Materials for Energy Storage Devices: A Review

“…The excess C in C 3 N (C 3.33 N) exhibited a high reversible capacity of 840.35 mAh g −1 with fast charging-discharging rate [205]. C 3 N/graphene has a theoretical capacity of 1079 mAh g −1 and exhibits good electric conductivity with high stability [206].…”

Recent Advances and Perspectives of Carbon-Based Nanostructures as Anode Materials for Li-ion Batteries