Tubular-like Nanocomposites with Embedded Cu 9 S 5 -MoS x Crystalline-Amorphous Heterostructure in N-Doped Carbon as Li-Ion Batteries Anode toward Ultralong Cycling Stability

• Published in: ACS applied materials & interfaces Vol. 16; no. 34; pp. 44678 - 44688
• Main Authors: Yu, Xiaoming, Yu, Hongxin, Yin, Linwei, Cai, Junjie
• Format: Journal Article
• Language: English
• Published: United States 28.08.2024
• Subjects: 1D hollow structure; crystalline−amorphous heterostructures; molybdenum sulfide; Li-ion batteries; Cu9S5
• ISSN: 1944-8244; 1944-8252
• DOI: 10.1021/acsami.4c06752

Transition metal sulfides (TMSs) show the potential to be competitive candidates as next-generation anode materials for Li-ion batteries (LIBs) due to their high theoretical specific capacity. However, sluggish ionic/electronic transportation and huge volume change upon lithiation/delithiation remain major challenges in developing practical TMS anodes. We rationally combine structural design and interface engineering to fabricate a tubular-like nanocomposite with embedded crystalline Cu S5 nanoparticles and amorphous MoS in a carbon matrix (C/Cu S -MoS NTs). On the one hand, the hybrid integrated the advantages of 1D hollow nanostructures and carbonaceous materials, whose high surface-to-volume ratios, inner void, flexibility, and high electronic conductivity not only enhance ion/electron transfer kinetics but also effectively buffer the volume changes of metal sulfides during charge/discharge. On the other hand, the formation of crystalline-amorphous heterostructures between Cu S and MoS could further boost charge transfer due to an induced built-in electric field at the interface and the presence of a long-range disorder phase. In addition, amorphous MoS offers an extra elastic buffer layer to release the fracture risk of Cu S crystalline nanoparticles during repetitive electrochemical reactions. Benefiting from the above synergistic effect, the C/Cu S -MoS electrode as an LIB anode in an ether-based electrolyte achieves a high-rate capability (445 mAh g at 6 A g ) and superior ultralong-term cycling stability, which delivers an initial discharge capacity of 561 mAh g at 2 A g and its retention capacity after 3600 cycles (376 mAh g ) remains higher than that of commercial graphite (372 mAh g ).