Silicon nanocrystals-embedded carbon nanofibers from hybrid polyacrylonitrile – TEOS precursor as high-performance lithium-ion battery anodes

“…Furthermore, as depicted in Figure 4c, the TEM image shows the expansion of in‐situ SiO 2 particles after several cycles. Decreasing the strain and stress caused by SiO 2 particles expansion is conductive to prolong anode cycling life [42] . As illustrated in Figure 4d, the explicit differences based on structure and materials of anodes were analyzed by the following illustration: i) the surface membrane CNFs can effectively reduce the differentiation and abscission of particles in the process of circulation; ii) significantly, the silica composite carbon spheres prepared by electrostatic spray greatly improve the loading of active particles in composite anode materials.…”

Preparation of a SiO₂@Carbon Sphere/SiO₂−CNF Multilayer Self‐standing Anode Prepared via an Alternate Electrospraying – Electrospinning Technique

“…Furthermore, as depicted in Figure 4c, the TEM image shows the expansion of in‐situ SiO 2 particles after several cycles. Decreasing the strain and stress caused by SiO 2 particles expansion is conductive to prolong anode cycling life [42] . As illustrated in Figure 4d, the explicit differences based on structure and materials of anodes were analyzed by the following illustration: i) the surface membrane CNFs can effectively reduce the differentiation and abscission of particles in the process of circulation; ii) significantly, the silica composite carbon spheres prepared by electrostatic spray greatly improve the loading of active particles in composite anode materials.…”

Preparation of a SiO₂@Carbon Sphere/SiO₂−CNF Multilayer Self‐standing Anode Prepared via an Alternate Electrospraying – Electrospinning Technique

“…Dirican et al 3 fabricated binder-free Si/SiO 2 /CNF composites with the first-cycle discharge capacity of 1206 mAh•g −1 at 0.1 A•g −1 . Hamedani et al 17 employed CNF-Si/ SiO x materials as LIB anodes without any binders, showing a reversible capacity of 860 mAh•g −1 at 0.2 A•g −1 . Additionally, structural design and heteroatom doping of carbon nanofibers are effective strategies to improve the electrochemical properties of Si/CNF composites.…”

“…Carbon materials have the advantages of good electrical conductivity and stable deintercalation of lithium. Therefore, Si and carbon materials like graphene, , porous carbon, , carbon nanotubes, , and carbon fibers ,, have been composited to enhance electrical conductivity, cyclic stability, and rate performance. In particular, carbon nanofibers (CNFs) are very promising anodes for LIBs, which possess good conductivity, high specific surface area, and freestanding properties.…”

Freestanding Porous Silicon@Heteroatom-Doped Porous Carbon Fiber Anodes for High-Performance Lithium-Ion Batteries

“…Additionally, the build-up of SEI debris may impair charge transfer characteristics, accelerating capacity deterioration. [12][13][14] Also, weak electronic conductivity and lithium-ion diffusivity in silicon further reduce electrode rate capability. 15 To overcome the drawbacks of silicon in lithium-ion batteries, new electrode materials with high specific capacity, stable mechanical structure, high electrical conductivity, and a short diffusion path for Li ion transport must be developed.…”

A Tripartite Composite Incorporating Nitrogen-Doped Graphene Oxide, Polypyrrole, and Silica for Lithium-Ion Battery Anodes