Facile synthesis of carbon and oxygen vacancy co-modified TiNb6O17 as an anode material for lithium-ion batteries

Yunfan Shang; Suyang Lu; Wei Zheng; Rui Wang; Zi Liang; Yushuo Huang; Jun Mei; Ye Yang; Wenwen Zeng; Haoran Zhan

doi:10.1039/d2ra01757a

Facile synthesis of carbon and oxygen vacancy co-modified TiNb₆O₁₇ as an anode material for lithium-ion batteries

RSC Adv. 2022 Apr 29;12(21):13127-13134. doi: 10.1039/d2ra01757a. eCollection 2022 Apr 28.

Authors

Yunfan Shang¹, Suyang Lu¹, Wei Zheng², Rui Wang², Zi Liang², Yushuo Huang¹, Jun Mei¹, Ye Yang¹, Wenwen Zeng¹, Haoran Zhan¹

Affiliations

¹ Chengdu Development Center of Science and Technology, China Academy of Engineering Physics Chengdu 610200 China zhanhenry20@163.com.
² Sichuan Global Creatives Corporation Battery Material CO., LTD Meishan 620000 China.

Abstract

Titanium niobium oxides (TNOs), benefitting from their large specific capacity and Wadsley-Roth shear structure, are competitive anode materials for high-energy density and high-rate lithium-ion batteries. Herein, carbon and oxygen vacancy co-modified TiNb₆O₁₇ (A-TNO) was synthesized through a facile sol-gel reaction with subsequent heat treatment and ball-milling. Characterizations indicated that A-TNO is composed of nanosized primary particles, and the carbon content is about 0.7 wt%. The nanoparticles increase the contact area of the electrode and electrolyte and shorten the lithium-ion diffusion distance. The carbon and oxygen vacancies decrease the charge transfer resistance and enhance the Li-ion diffusion coefficient of the obtained anode material. As a result of these advantages, A-TNO exhibits excellent rate performance (208 and 177 mA h g^-1 at 10C and 20C, respectively). This work reveals that A-TNO possesses good electrochemical performance and has a facile preparation process, thus A-TNO is believed to be a potential anode material for large-scale applications.