Preparation and application of Cr8O21 as cathode material for high specific energy lithium batteries

doi:10.19799/j.cnki.2095-4239.2022.0372

Abstract

Abstract:

Cr₈O₂₁ is considered as a potential cathode material due to its high specific capacity and low cost. However, Cr₈O₂₁ can be only applied in primary batteries due to the large first-cycle irreversible capacity and the poor cycle stability. Currently, Cr₈O₂₁ is usually synthesized under high pressure or normal pressure under oxygen atmosphere. This procedure is dangerous and prone to generate impurity. Herein, the pure-phase Cr₈O₂₁ was prepared by two-step pyrolysis of CrO₃ under air atmosphere. The electrochemical performance of the as-prepared Cr₈O₂₁ cathode was investigated. X-ray photoelectron spectroscopy (XPS) and X-ray diffraction (XRD) were used to investigate the electrochemical reaction mechanism of Cr₈O₂₁. The as-prepared Cr₈O₂₁delivers a high initial discharge specific capacity of 400.4 mAh/g and a specific energy of 1218 Wh/kg at 0.1 C. The reversible specific capacity is 304.4 mAh/g and a reversible capacity retention of 88.7% is achieved after 100 cycles, exhibiting good electrochemical performance and cycling stability. The crystal structure of Cr₈O₂₁ consists of two [CrO₆] sublattice units and one [CrO₄] sublattice unit, in hich the [CrO₄] is located between the two [CrO₆] sublattice units. XPS tests reveal that the redox reaction of Cr₈O₂₁ involving three-electron transfer between Cr⁶⁺and Cr³⁺ occurs during charging and discharging process. XRD tests indicate that the sublattice of [CrO₄] in Cr₈O₂₁ transfer to amorphous after the intercalation of Li-ions which corresponding to the first plateau at the initial discharge curve. Furthermore, at the second discharge plateau, the microcrystals of LiCrO₂ are generated. During the subsequent cycling, LiCrO₂ is electrochemically oxidized and reduced reversibly, suggesting the good rechargeable capability of Cr₈O₂₁.

Key words: lithium battery, Cr₈O₂₁, two-step pyrolysis, chromium-based oxides cathode

CLC Number:

TQ 152

Miaomiao CHEN, Qinjun SHAO, Jian CHEN. Preparation and application of Cr₈O₂₁ as cathode material for high specific energy lithium batteries[J]. Energy Storage Science and Technology, 2022, 11(9): 3011-3020.

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圈数	R_s/Ω	R_SEI/Ω	R_ct/Ω
Pristine	2.8	22.5	445.2
1	3.6	19.8	336.9
2	2.3	31.1	109.8
3	2.6	28.8	36.4
4	3.0	27.8	28.0
5	3.0	27.0	22.4

材料	电流	首次放电比容量 /(mAh/g)	循环圈数/比容量 /(mAh/g)	参考文献
CrO_2.653	0.1 mA /cm²	255	50/210	[9]
Cr₃O₈	0.17 C	322	100/240	[10]
Cr₈O₂₁	0.16 mA /cm²	395	50/255	[11]
Co_0.2CrO _x	0.5 mA /cm²	290	100/240	[17]
Cr₈O₂₁	0.1 C	400.4	100/269.9	This work

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Preparation and application of Cr₈O₂₁ as cathode material for high specific energy lithium batteries

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