一种高熵磷酸盐正极宿主实现高稳定性锂硫电池

doi:10.6023/A23020020

摘要/Abstract

锂硫电池由于高能量密度和成本低等优势有望成为下一代高比能二次电池. 然而中间产物多硫化物的穿梭效应以及滞后的反应动力学严重阻碍了其实际应用. 本研究通过一步喷雾热解得到了一种高熵金属磷酸盐(HEPi)催化剂, 将其应用于硫正极宿主. HEPi丰富的多孔结构不仅有利于实现硫的封装、限域, 保证电解液的充分浸润, 而且其对多硫化物的化学吸附有增强作用, 同时能够加速多硫化物的快速转化, 从而抑制多硫化物的穿梭效应, 提高了硫的活性物质利用率. 测试结果表明, 组装的电池容量在0.1 C电流密度下能获得1477.3 mAh•g^-1的高放电容量. 即使在2 C高的电流密度下, 其容量仍能保持在782 mAh•g^-1. 本工作为高熵材料在锂硫电池中的应用提供了前景.

关键词: 锂硫电池, 高熵材料, 催化作用, 化学吸附, 穿梭效应

With the rapid development of portable electronic devices, electric vehicles and large-scale energy storage, higher energy density energy storage devices are needed to replace traditional lithium-ion batteries. Lithium-sulfur batteries (LSBs) are expected to be the next generation of high-specific capacity secondary batteries due to the high energy density (2600 Wh•kg^-1) and low cost ($ 150 ton^-1). However, LSBs also face serious problems, including poor rate performance and short cycle life. These problems are rooted in the insulating nature of sulfur, the shuttle effect of the intermediate phase lithium polysulfide (LiPSs), and sluggish reaction of sulfur redox reaction. Severe shuttle effects can cause LiPSs to diffuse into the lithium cathode and deposit on the Li metal surface, leading to the loss of active material; the insulating properties of sulfur and the reaction barrier also greatly limit the multiplier performance of lithium-sulfur batteries. The use of electrochemical catalysts to accelerate the conversion between LiPSs and lithium sulfide is currently an effective solution. Among them, high-entropy compounds have attracted a lot of attention. High entropy compounds are composed of multiple metallic elements uniformly distributed in the solid solution, and the catalytic activity and stability of these compounds are significantly enhanced due to the synergistic effect and high entropic stability. However, currently developed multi-elemental and high-entropy compounds are limited to single anion species such as oxides, carbides and sulfides, which have relatively simple molecular structures. Although the choice of combinatorial elements has been broadened by introducing the concept of high entropy, there is still a vast scope for development by extending the synthetic capabilities to more complex systems such as polyanionic materials. In this study, a high-entropy metal phosphate (HEPi) catalyst is obtained by one-step spray pyrolysis and applied to the sulfur cathode host. The rich porous structure of HEPi not only facilitates the encapsulation and domain-limiting of sulfur and ensures the sufficient infiltration of electrolyte, but also enhances the chemisorption of polysulfides and accelerates the rapid conversion of polysulfides, thus suppressing the shuttle effect of polysulfides and improving the utilization of sulfur. The results show that the assembled cell can obtain a high discharge capacity of 1477.3 mAh•g^-1 at a current density of 0.1 C. The capacity can be maintained at 782 mAh•g^-1 even at a high current density of 2 C. This work offers a prospect for the application of high-entropy materials in lithium-sulfur batteries.

Key words: lithium-sulfur battery, high-entropy material, catalysis, chemical adsorption, shuttle effect

引用此文

赵振新, 姚一琨, 陈佳骏, 牛蓉, 王晓敏. 一种高熵磷酸盐正极宿主实现高稳定性锂硫电池[J]. 化学学报, 2023, 81(5): 496-501.

Zhao Zhenxin, Yao Yikun, Chen Jiajun, Niu Rong, Wang Xiaomin. A High-entropy Phosphate Cathode Host towards High-stability Lithium-sulfur Batteries[J]. Acta Chimica Sinica, 2023, 81(5): 496-501.

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图/表 5

图1. (a) HEPi的制备原理图, (b) 电感耦合等离子体(ICP)测试结果, (c) FePi, (d) FeCoNiPi和(e) HEPi的扫描电子显微镜图(SEM)和X射线能谱分析(EDS), 标尺为500 nm, (f) HEPi的高倍透射电子显微镜的能谱图, (g) HEPi低倍扫描电子显微镜图, (h~k) HEPi的透射电子显微镜图

Figure 1. (a) The preparation method of HEPi, (b) the results of ICP tests, SEM images and EDS plots of (c) FePi, (d) FeCoNiPi and (e) HEPi, the scale of (c~e) is 500 nm, (f) EDS plots of high-resolution TEM of HEPi, (g) low-resolution SEM image and (h~k) TEM images of HEPi

图2. (a) HEPi的XRD图谱, (b) Raman图谱, (c) N2吸脱附曲线, (d)孔径分布图

Figure 2. (a) XRD patterns of HEPi, (b) Raman spectra, (c) N2 adsorption-desorption isotherms and (d) pore size distribution of HEPi

图3. (a) XPS谱图, (b) Fe 2p, (c) Co 2p, (d) Ni 2p, (e) Cr 2p, (f) Mn 2p的高分辨图谱

Figure 3. (a) XPS spectrum, (b) high-resolution XPS spectra of (b) Fe 2p, (c) Co 2p, (d) Ni 2p, (e) Cr 2p, (f) Mn 2p

图4. (a) 0.1 C电流密度循环性能及(b)充放电曲线图, (c)倍率性能图, (d) 2 C电流密度的循环性能, (e)抑制穿梭效应机理图

Figure 4. (a) Cycling performance at 0.1 C, (b) charge-discharge profiles, (c) rate performance, (e) cycling performance at 2 C, (e) the diagram of reducing shuttle effect

图5. (a)循环伏安曲线, (b)氧化峰位置和(c)第一个还原峰位置对应的塔菲尔曲线, (d) KB/S和(e) HEPi/S的不同温度阻抗图谱, (f)基于不同温度阻抗拟合获得的阿伦尼乌斯图谱

Figure 5. (a) CV profiles, the calculated Tafel plots of (b) oxidation peak and (c) the first reduction peak, EIS plots of different temperatures of (d) KB/S and (e) HEPi/S, (f) Arrhenius plots based on the resistance of different temperatures

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