Two-dimensional organic-inorganic heterostructures of in situ-grown layered COF on Ti3C2 MXene nanosheets for lithium-sulfur batteries

• Published in: Nano today Vol. 35; p. 100991
• Main Authors: Meng, Ruijin, Deng, Qiyi, Peng, Chengxin, Chen, Bingjie, Liao, Kexuan, Li, Lunjin, Yang, Ziyi, Yang, Donglei, Zheng, Lei, Zhang, Chi, Yang, Jinhu
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.12.2020
• Subjects: Covalent organic framework; Dual-site adsorption; High sulfur content; Li-S batteries; Ti3C2 nanosheets; Covalent organic framework; High sulfur content; Ti3C2 nanosheets; Dual-site adsorption; Li-S batteries
• ISSN: 1748-0132; 1878-044X
• DOI: 10.1016/j.nantod.2020.100991

The constructed CTF/TNS heterostructures show superior Li-S battery performance as a sulfur host due to their multiple-in-one advantages of 3D spatial sulfur confinement, dual-site chemical polysulfides anchoring and efficient electron/ion transport. [Display omitted] •2D heterostructures of layered CTF in situ-grown on Ti3C2 nanosheets were fabricated.•Covalent Ti-N interaction between TNS and CTF components enabled a stable interface.•The 2D heterostructures held multiple-in-one advantages for superior Li-S batteries.•Li-S batteries based on the 2D heterostructures showed outstanding cycling stability. The development of sulfur host materials with simultaneous suppressed shuttle effect, improved electrical/ionic conductivity and high sulfur loading is highly desired for lithium-sulfur batteries. Herein, we proposed that two-dimensional heterostructures made of layered covalent triazine framework on Ti3C2 MXene nanosheets (CTF/TNS) as a sulfur host show multiple-in-one advantages for lithium-sulfur batteries. The integrity of organic CTF with ordered pore structure and inorganic TNSs with high conductivity imparts the heterostructures three-dimensional spatial confinement for high sulfur loading and efficient electron/ion transport for improved reaction kinetics. In addition, lithiophilic N sites in CTF and sulfurophilic Ti sites in TNSs enable dual-site chemical anchoring of polysulfides to effectively suppress shuttle effect. With a high sulfur loading of 76 wt%, the S@CTF/TNS cathode shows high reversible capacity (1441 mA h g−1 at 0.2 C), outstanding cycling stability (up to 1000 cycles at 1 C with a 0.014 % capacity decay rate per cycle) and excellent rate capability. Notably, even with a high areal sulfur loading of 5.6 mg cm−2, a high capacity retention of 94 % is still obtained after 100 cycles.