Preperation and Electrochemical Performance of Rare Earth La3+-doped Vanadium Dioxide

doi:10.11901/1005.3093.2025.155

Chinese Journal of Materials Research

2026, Vol. 40

Issue (4): 313-320 DOI: 10.11901/1005.3093.2025.155

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Preperation and Electrochemical Performance of Rare Earth La³⁺-doped Vanadium Dioxide

ZHAO Ruize, TIAN Li(

), SONG Peiyuan, FANG Yao, SUN Meng, FAN Sainan, OU Zhimin, ZHU Haibo, HUANG Rongjiao, YANG Li

School of Materials Science and Engineering, Hunan Provincial Key Laboratory of Advanced Materials for New Energy Storage and Conversion, Hunan University of Science and Technology, Xiangtan 411201, China

Cite this article:

ZHAO Ruize, TIAN Li, SONG Peiyuan, FANG Yao, SUN Meng, FAN Sainan, OU Zhimin, ZHU Haibo, HUANG Rongjiao, YANG Li. Preperation and Electrochemical Performance of Rare Earth La³⁺-doped Vanadium Dioxide. Chinese Journal of Materials Research, 2026, 40(4): 313-320.

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Abstract

Regarding the structural instability and poor cycling performance of vanadium-based oxide cathode materials during the charge-discharge processes in aqueous zinc-ion batteries, a series of La³⁺-doped VO₂ materials (La³⁺-VO₂) have been synthesized via a simple hydrothermal method. The results of electrochemical measurement indicate that an appropriate amount of rare-earth La³⁺-doping could enhance the rate capability and cycling stability of VO₂ electrodes. When the V:La molar ratio is 2:0.3, the prepared La³⁺-VO₂ electrode exhibits a specific capacity of 160.2 mAh·g^-1 at a current density of 0.1 A·g^-1 and a discharge specific capacity of 131.9 mAh·g^-1 with a capacity retention rate of 82% after 100 cycles. The rate capability tests reveal the electrode with a maximum specific capacity of 209.8 mAh·g^-1 at a current density of 0.1 A·g^-1 and with a capacity of 60.8 mAh·g^-1 at a high current density of 5.0 A·g^-1, and with a maximum specific capacity of 217.6 mAh·g^-1 when the current density returned 0.1 A·g^-1, showing good reversibility and structural stability of the La³⁺-VO₂ electrodes. The electrode maintains a specific capacity of 52.2 mAh·g^-1 after 1000 cycles at 1.0 A·g^-1 demonstrating good cycling performance even at high current densities. The electrochemical kinetic analysis indicates that the charge-discharge process of the La³⁺-VO₂ electrode is simultaneously governed by both capacitive and diffusion-controlled reactions with the pseudocapacitive contribution percentages of 77% and 88% at scan rates of 0.2 mV·s^-1 and 1.0 mV·s^-1, respectively showing its fast kinetic behavior. The contribution of the capacitive charge storage mechanism ensures the excellent cycling stability of the La³⁺-VO₂ electrode at high capacity and high-rate conditions.

Key words: inorganic non-metallic materials aqueous zinc-ion battery hydrothermal method vanadium dioxide

Received: 24 April 2025

ZTFLH:

TQ152

Fund: National Natural Science Foundation of China(51202066);Program for New Century Excellent Talents in University(NCET-13-0784);National College Student Innovation and Entrepreneurship Training Program(202510534057);Hunan Province Postgraduate Research Innovation Project(CX20251560);National College Student Innovation and Entrepreneurship Training Program(S202510534131);Teaching Reform Research Project (No.G325E3) and Student Research and Innovation Program (No.YZ2553) of Hunan University of Science and Technology(G325E3)

Corresponding Authors: TIAN Li, Tel: 18627323439, E-mail: 849050031@qq.com

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	Articles by authors
	ZHAO Ruize
	TIAN Li
	SONG Peiyuan
	FANG Yao
	SUN Meng
	FAN Sainan
	OU Zhimin
	ZHU Haibo
	HUANG Rongjiao
	YANG Li

URL:

https://www.cjmr.org/EN/10.11901/1005.3093.2025.155 OR https://www.cjmr.org/EN/Y2026/V40/I4/313

Fig.1 XRD patterns of La³⁺ pre-intercalated VO₂ electrode materials

Fig.2 EDS pattern and element distribution (inset) of La³⁺-doped VO₂ electrode materials (0.30La³⁺-VO₂)

Fig.3 SEM images of 0La³⁺-VO₂ sample (a-d) and 0.3La³⁺-VO₂sample (e-h)

Fig.4 First three cycles of cyclic voltammetry curves of 0La³⁺-VO₂ (a), 0.15La³⁺-VO₂ (b), 0.3La³⁺-VO₂ (c) and 0.45La³⁺-VO₂ (d) at a scan rate of 0.1 mV·s^-1

Fig.5 Cycling performance of La³⁺-VO₂ (a) and GCD curves of 0.30La³⁺-VO₂ at 0.1 A·g^-1 (b)

Fig.6 Rate performance of La³⁺-VO₂ (a) and GCD curves of 0.30La³⁺-VO₂ at different current densities ranging from 0.1 A·g^-1 to 5.0 A·g^-1 (b)

Fig.7 Cycling performance of La³⁺-VO₂ at 1.0 A·g^-1

Fig.8 First cycle Nyquist curves of La³⁺-VO₂

Fig.9 CV curves of 0.3La³⁺-VO₂ (a) and 0.45La³⁺-VO₂ (b) at different scan rates and b-value fitting graphs for 0.30La³⁺-VO₂(c) and 0.45La³⁺-VO₂ samples (d)

Fig.10 Pseudocapacitance contribution ratio of 0.30La³⁺-VO₂ (a) and 0.45La³⁺-VO₂ (b) at 0.2 mV·s^-1 and capacitive contribution rate of 0.30La³⁺-VO₂ (c) and 0.45La³⁺-VO₂ (d) samples at different scan rates

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