Recent progress in organics derived cathode materials for lithium sulfur batteries

doi:10.19799/j.cnki.2095-4239.2020.0126

Abstract

Abstract:

Lithium-sulfur (Li-S) batteries have attracted tremendous attention due to their high energy density, low cost, and environmental friendliness. However, the integration of intrinsic low conductivity (S/Li2S) and shuttle effects (polysulfides) may confine the utilization of active sulfur and cause serious volume expansion of active sites, therefore leading to a rapid capacity decrease during long-term cycles. In recent years, some publications have suggested that elemental sulfur could be fused at high temperature to form linear chain sulfur fragments and subsequently form organic sulfur copolymers via high temperature cyclization, which is considered an effective strategy to cope with the poor cyclic stability of the traditional Li-S system. In this review, first, we examine the reaction mechanisms and shortcomings of traditional Li-S batteries. Then, we review the synthesis methods, lithium storage mechanism, research progress of various active groups (nitrile, unsaturated hydrocarbon, thiol group, and micro-molecule organosulfide) and molten sulfur, list the dis/advantages of organosulfur polymer systems, and suggest strategies and outlooks according to scientific views. In summary, organic sulfur copolymers can efficiently reduce the shuttle effects of traditional C/S batteries, due to the whole/partial active sulfur fragment integrated into the cathode. Such organic sulfur copolymers may simultaneously achieve high sulfur loading and long cycling stability.

Key words: organosulfur polymers, cathode materials, lithium-sulfur batteries, long cycling stability

CLC Number:

TM 912

Yun LU, Jianing LIANG, Yong ZHU, Zhengrong LI, Yezhou HU, Ke CHEN, Deli WANG. Recent progress in organics derived cathode materials for lithium sulfur batteries[J]. Energy Storage Science and Technology, 2020, 9(5): 1454-1466.

Figures/Tables 9

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Table 1

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放电产物	转移电子数	放电深度	放电比容量 /mA·h·g^-1
放电产物	mol × mol^-1·S	DOD	放电比容量 /mA·h·g^-1
S₈→S₈^2-	0.25	12.5%	210
S₈→S₆^2-	0.33	16.7%	280
S₈→S₄^2-	0.5	25.0%	420
S₈→Li₂S₂^2-	1	50.0%	840
S₈→Li₂S^2-	2	100.0%	1680

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