Superimposed Effect of La Doping and Structural Engineering to Achieve Oxygen-Deficient TiNb 2 O 7 for Ultrafast Li-Ion Storage.
Kangdong TianZhongxiao WangHaoxiang DiHaoyu WangZhiwei ZhangShoubao ZhangRutao WangLuyuan ZhangChengxiang WangLong-Wei YinPublished in: ACS applied materials & interfaces (2022)
TiNb 2 O 7 (TNO) is a competitive candidate of a fast-charging anode due to its high specific capacity. However, the insulator nature seriously hinders its rate performance. Herein, the La 3+ -doped mesoporous TiNb 2 O 7 materials (La-M-TNO) were first synthesized via a facile one-step solvothermal method with the assistance of polyvinyl pyrrolidone (PVP). The synergic effect of La 3+ doping and the mesoporous structure enables a dual improvement on the electronic conductivity and ionic diffusion coefficient, which delivers an impressive specific capacity of 213 mAh g -1 at 30 C. The capacity retention (@30C/@1C) increases from 33 to 53 and 74% for TNO, M-TNO, and La-M-TNO (0.03), respectively, demonstrating a step-by-step improvement of rate performance by making porous structures and intrinsic conductivity enhancement. DFT calculations verify that the enhancement in electronic conductivity due to La 3+ doping and oxygen vacancy, which induce localized energy levels via slight hybridization of O 2p, Ti 3d, and Nb 4d orbits. Meanwhile, the GITT result indicates that PVP-induced self-assembly of TNO accelerates the lithium ion diffusion rate by shortening the Li + diffusion path. This work verifies the effectiveness of the porous structure and highlights the significance of electronic conductivity to rate performance, especially at >30C. It provides a general approach to low-conductivity electrode materials for fast Li-ion storage.
Keyphrases
- metal organic framework
- ion batteries
- solid state
- highly efficient
- quantum dots
- randomized controlled trial
- systematic review
- density functional theory
- computed tomography
- reduced graphene oxide
- molecular dynamics
- oxidative stress
- magnetic resonance
- single molecule
- drug induced
- diabetic rats
- ionic liquid
- endothelial cells
- energy transfer
- label free
- oxide nanoparticles