基于固-固反应机制锂硫电池的最新研究进展
收稿日期: 2024-01-29
网络出版日期: 2024-02-27
基金资助
贵州轻工职业技术学院自然科学研究项目(23QY01);贵州省科学技术基金资助项目(黔科合基础-ZK[2024]一般608);贵州省科学技术基金资助项目(黔科合基础-[2018]1086);贵州省科学技术基金资助项目(黔科合平台人才-CXTD[2023]016)
Recent research progress of lithium-sulfur batteries based on solid-solid reaction mechanism
Received date: 2024-01-29
Online published: 2024-02-27
锂硫电池具有高的理论能量密度,且单质硫存在环境友好和价格低廉等优势,被认为是发展前景良好的储能器件。然而,硫在常规醚类电解液中进行充放电是基于固-液-固两相转换的反应机制,会生成溶解性较高的中间产物多硫化锂从而引发穿梭效应,导致活性物质不可逆流失和锂负极腐蚀。因此,发展不涉及液相多硫化锂溶解于电解液的固-固反应机制尤为重要。大量研究证明,通过优化正极材料设计、调控电解质体系及其协同设计等策略,可实现硫正极的固-固反应机制,避免多硫化锂溶解于电解液,从而提升锂硫电池的电化学性能。主要综述了硫正极实现固-固机制的可行途径并进行了机理探讨,最后对构筑高能量密度实用化锂硫电池的发展提出了展望,旨在解决贫电解液条件下锂负极腐蚀和硫正极基于固-固反应机制存在反应动力学缓慢的问题。
陈雪 , 欧阳全胜 , 邵姣婧 . 基于固-固反应机制锂硫电池的最新研究进展[J]. 无机盐工业, 2024 , 56(9) : 12 -23 . DOI: 10.19964/j.issn.1006-4990.2024-0059
Lithium sulfur batteries are considered to be promising energy storage devices due to their high theoretical energy density,as well as the advantages of environmental friendliness and low-cost of sulfur.However,sulfur cathodes usually react with lithium ions under solid-liquid-solid biphasic reaction mechanism in conventional ether-based electrolytes,which generates intermediate products of lithium polysulfides and leads to the irreversible loss of active materials and corrosion of lithium anodes.Hence,it is vital to develop sulfur cathodes operating on sold-solid reaction mechanism without dissolving of lithium polysulfides into electrolytes.At present,vast research revealed that the realization of sulfur cathodes based on solid-solid reaction mechanism could be achieved by rational design of cathode materials,regulating the electrolyte systems,or their synergistic design,which thus improved the electrochemical performance of lithium sulfur batteries.The strategies towards achieving solid-solid reaction mechanism of sulfur cathodes in recent years were summarized and the detailed mechanism was discussed.Finally,the development prospect of constructing practical lithium-sulfur batteries with high energy density was put forward,aiming at solving the problems of lithium anode corrosion under the condition of lean electrolyte and the sluggish reaction kinetics based on the solid-solid reaction mechanism of sulfur cathode.
| 1 | 况新亮,刘垂祥,熊朋.锂离子电池产业分析及市场展望[J].无机盐工业,2022,54(8):12-19,32. |
| KUANG Xinliang, LIU Chuixiang, XIONG Peng.Industry analysis and market prospect of lithium ion battery[J].Inorganic Chemicals Industry,2022,54(8):12-19,32. | |
| 2 | 胡倩倩,王清泉,吕少茵,等.高导多孔导电碳材料的合成及其在高能量密度锂硫电池中的应用[J].新能源进展,2023,11(6):519-523. |
| HU Qianqian, WANG Qingquan, Shaoyin Lü,et al.Synthesis and application of carbon material with high conductivity and multiple pores for high-energy lithium sulfur batteries[J].Advances in New and Renewable Energy,2023,11(6):519-523. | |
| 3 | HOU Jianhua, TU Xinyue, WU Xiaoge,et al.Remarkable cycling durability of lithium-sulfur batteries with interconnected mesoporous hollow carbon nanospheres as high sulfur content host[J].Chemical Engineering Journal,2020,401:126141. |
| 4 | MOON S, JUNG Y H, JUNG W K,et al.Encapsulated monoclinic sulfur for stable cycling of Li-S rechargeable batteries[J].Advanced Materials,2013,25(45):6547-6553. |
| 5 | HAN P, CHUNG S H, MANTHIRAM A.Pyrrolic-type nitrogen-doped hierarchical macro/mesoporous carbon as a bifunctional host for high-performance thick cathodes for lithium-sulfur batteries[J].Small,2019,15(16):1900690. |
| 6 | D?RFLER S, ALTHUES H, H?RTEL P,et al.Challenges and key parameters of lithium-sulfur batteries on pouch cell level[J].Joule,2020,4(3):539-554. |
| 7 | 王维坤,王安邦,金朝庆.锂硫电池的实用化挑战[J].储能科学与技术,2020,9(2):593-597. |
| WANG Weikun, WANG Anbang, JIN Zhaoqing.Challenges on practicalization of lithium sulfur batteries[J].Energy Storage Science and Technology,2020,9(2):593-597. | |
| 8 | ZHAO Meng, LI Boquan, PENG Hongjie,et al.Lithium-sulfur batteries under lean electrolyte conditions:Challenges and opportunities[J].Angewandte Chemie International Edition,2020,59(31):12636-12652. |
| 9 | FAN F Y, CHIANG Y M.Electrodeposition kinetics in Li-S batteries:Effects of low electrolyte/sulfur ratios and deposition surface composition[J].Journal of the Electrochemical Society,2017,164(4):A917-A922. |
| 10 | HE Feng, WU Xiangjiang, QIAN Jiangfeng,et al.Building a cycle-stable sulphur cathode by tailoring its redox reaction into a solid-phase conversion mechanism[J].Journal of Materials Chemistry A,2018,6(46):23396-23407. |
| 11 | HUANG Feifei, GAO Lujie, ZOU Yiping,et al.Akin solid-solid biphasic conversion of a Li-S battery achieved by coordinated carbonate electrolytes[J].Journal of Materials Chemistry A,2019,7(20):12498-12506. |
| 12 | 陈雪.“固—固” 反应硫正极的界面构筑与电化学性能研究[D].武汉:华中科技大学,2022. |
| CHEN Xue.Study on interfacial construction and electrochemical properties of “solid-solid”reaction of sulfur cathode[D].Wuhan:Huazhong University of Science and Technology,2022. | |
| 13 | ZHANG B, QIN X, LI G R,et al.Enhancement of long stability of sulfur cathode by encapsulating sulfur into micropores of carbon spheres[J].Energy & Environmental Science,2010,3(10):1531-1537. |
| 14 | XIN Sen, GU Lin, ZHAO Nahong,et al.Smaller sulfur molecules promise better lithium-sulfur batteries[J].Journal of the American Chemical Society,2012,134(45):18510-18513. |
| 15 | LI Zhen, YUAN Lixia, YI Ziqi,et al.Insight into the electrode mechanism in lithium-sulfur batteries with ordered microporous carbon confined sulfur as the cathode[J].Advanced Energy Materials,2014,4(7):1301473. |
| 16 | LI Shanshan, JIN Bo, ZHAI Xiaojie,et al.Review of carbon materials for lithium-sulfur batteries[J].ChemistrySelect,2018,3(8):2245-2260. |
| 17 | HU Lei, LU Yue, LI Xiaona,et al.Optimization of microporous carbon structures for lithium-sulfur battery applications in carbonate-based electrolyte[J].Small,2017,13(11):1603533. |
| 18 | PAN Zhiyong, BRETT D J L, HE Guanjie,et al.Progress and perspectives of organosulfur for lithium-sulfur batteries[J].Advanced Energy Materials,2022,12(8):2103483. |
| 19 | ZHAO Xiaohui, WANG Chonglong, LI Ziwei,et al.Sulfurized polyacrylonitrile for high-performance lithium sulfur batteries:Advances and prospects[J].Journal of Materials Chemistry A,2021,9(35):19282-19297. |
| 20 | WANG Jiulin, YANG Jun, XIE Jiajun,et al.A novel conductive polymer-sulfur composite cathode material for rechargeable lithi-um batteries[J].Advanced Materials,2002,14(13/14):963-965. |
| 21 | DOAN T N L, GHAZNAVI M, ZHAO Yan,et al.Binding mechanism of sulfur and dehydrogenated polyacrylonitrile in sulfur/polymer composite cathode[J].Journal of Power Sources,2013,241:61-69. |
| 22 | YU Xianguo, XIE Jingying, YANG Jun,et al.Lithium storage in conductive sulfur-containing polymers[J].Journal of Electroanalytical Chemistry,2004,573(1):121-128. |
| 23 | JIN Zhaoqing, LIU Yonggang, WANG Weikun,et al.A new insight into the lithium storage mechanism of sulfurized polyacrylonitrile with no soluble intermediates[J].Energy Storage Materials,2018,14:272-278. |
| 24 | WANG Wenxi, CAO Zhen, ELIA G A,et al.Recognizing the mechanism of sulfurized polyacrylonitrile cathode materials for Li-S batteries and beyond in Al-S batteries[J].ACS Energy Letters,2018,3(12):2899-2907. |
| 25 | PANG Quan, LIANG Xiao, KWOK C Y,et al.Review:The importance of chemical interactions between sulfur host materials and lithium polysulfides for advanced lithium-sulfur batteries[J].Journal of the Electrochemical Society,2015,162(14):A2567-A2576. |
| 26 | YI Yikun, Feng HAI, TIAN Xiaolu,et al.A novel sulfurized polypyrrole composite for high-performance lithium-sulfur batteries based on solid-phase conversion[J].Chemical Engineering Journal,2023,466:143303. |
| 27 | LI Xiang, LIU Dezhong, CAO Ziyi,et al.Uncovering the solid-phase conversion mechanism via a new range of organosulfur polymer composite cathodes for lithium-sulfur batteries[J].Journal of Energy Chemistry,2023,84:459-466. |
| 28 | LI Xia, LUSHINGTON A, SUN Qian,et al.Safe and durable high-temperature lithium-sulfur batteries via molecular layer deposited coating[J].Nano Letters,2016,16(6):3545-3549. |
| 29 | LI Xia, BANIS M, LUSHINGTON A,et al.A high-energy sulfur cathode in carbonate electrolyte by eliminating polysulfides via solid-phase lithium-sulfur transformation[J].Nature Communications,2018,9:4509. |
| 30 | CHEN Xue, YUAN Lixia, LI Zhen,et al.Realizing an applicable “solid→solid” cathode process via a transplantable solid electrolyte interface for lithium-sulfur batteries[J].ACS Applied Materials & Interfaces,2019,11(33):29830-29837. |
| 31 | MARKEVICH E, SALITRA G, ROSENMAN A,et al.The effect of a solid electrolyte interphase on the mechanism of operation of lithium-sulfur batteries[J].Journal of Materials Chemistry A,2015,3(39):19873-19883. |
| 32 | LEE J T,EOM K, WU Feixiang,et al.Enhancing the stability of sulfur cathodes in Li-S cells via in situ formation of a solid electrolyte layer[J].ACS Energy Letters,2016,1(2):373-379. |
| 33 | CHEN Xue, JI Haijin, RAO Zhixiang,et al.Insight into the fading mechanism of the solid-conversion sulfur cathodes and designing long cycle lithium-sulfur batteries[J].Advanced Energy Materials,2022,12(1):2102774. |
| 34 | ZHU Qiancheng, YE Chun, MAO Deyu.Solid-state electrolytes for lithium-sulfur batteries:Challenges,progress,and strategi-es[J].Nanomaterials,2022,12(20):3612. |
| 35 | YI Jingguang, CHEN Long, LIU Yongchang,et al.High capacity and superior cyclic performances of all-solid-state lithium-sulfur batteries enabled by a high-conductivity Li10SnP2S12 solid electrolyte[J].ACS Applied Materials & Interfaces,2019,11(40):36774-36781. |
| 36 | WU Jinghua, LIU Sufu, HAN Fudong,et al.Lithium/sulfide all-solid-state batteries using sulfide electrolytes[J].Advanced Materials,2021,33(6):e2000751. |
| 37 | KANNO R, MURAYAMA M.Lithium ionic conductor thio-LISICON:The Li2S-GeS2-P2S5 system[J].Journal of the Electrochemical Society,2001,148(7):A742. |
| 38 | ZHU Pei, YAN Chaoyi, ZHU Jiadeng,et al.Flexible electrolyte-cathode bilayer framework with stabilized interface for room-temperature all-solid-state lithium-sulfur batteries[J].Energy Storage Materials,2019,17:220-225. |
| 39 | HAN Qigao, LI Xuelei, SHI Xixi,et al.Outstanding cycle stability and rate capabilities of the all-solid-state Li-S battery with a Li7P3S11 glass-ceramic electrolyte and a core-shell S@BP2000 nanocomposite[J].Journal of Materials Chemistry A,2019,7(8):3895-3902. |
| 40 | XU Kangli, LIU Xiaojing, LIANG Jianwen,et al.Manipulating the redox kinetics of Li-S chemistry by tellurium doping for improved Li-S batteries[J].ACS Energy Letters,2018,3(2):420-427. |
| 41 | SUN Fugen, ZHANG Bo, TANG Hao,et al.Heteroatomic Te x S1- x molecule/C nanocomposites as stable cathode materials in carbonate-based electrolytes for lithium-chalcogen batteries[J].Jo-urnal of Materials Chemistry A,2018,6(21):10104-10110. |
| 42 | LI Shuping, HAN Zhilong, HU Wei,et al.Manipulating kinetics of sulfurized polyacrylonitrile with tellurium as eutectic accelera tor to prevent polysulfide dissolution in lithium-sulfur battery under dissolution-deposition mechanism[J].Nano Energy,2019,60:153-161. |
| 43 | CHEN Xin, PENG Linfeng, WANG Lihui,et al.Ether-compatible sulfurized polyacrylonitrile cathode with excellent performance enabled by fast kinetics via selenium doping[J].Nature Communications,2019,10:1021. |
| 44 | LI Xiaona, LIANG Jianwen, ZHANG Kailong,et al.Amorphous S-rich S1- x Se x /C (x≤0.1) composites promise better lithium-sulfur batteries in a carbonate-based electrolyte[J].Energy & Environmental Science,2015,8(11):3181-3186. |
| 45 | XU Guiliang, SUN Hui, LUO Chao,et al.Solid-state lithium/selenium-sulfur chemistry enabled via a robust solid-electrolyte interphase[J].Advanced Energy Materials,2019,9(2):1802235. |
| 46 | LI Shuping, MA Jingqi, ZENG Ziqi,et al.Enhancing the kinetics of lithium-sulfur batteries under solid-state conversion by using tellurium as a eutectic accelerator[J].Journal of Materials Chemistry A,2020,8(6):3405-3412. |
| 47 | SHEN Zeyu, ZHANG Weidong, MAO Shulan,et al.Tailored electrolytes enabling practical lithium-sulfur full batteries via interfacial protection[J].ACS Energy Letters,2021,6(8):2673-2681. |
| 48 | YANG Huijun, QIAO Yu, CHANG Zhi,et al.Designing cation-solvent fully coordinated electrolyte for high-energy-density lithium-sulfur full cell based on solid-solid conversion[J].Angewandte Chemie(International Ed.in English),2021,60(32):17726-17734. |
| 49 | CHEN Jiahang, LU Huichao, ZHANG Xuan,et al.Electrochemical polymerization of nonflammable electrolyte enabling fast-charging lithium-sulfur battery[J].Energy Storage Materials,2022,50:387-394. |
| 50 | HU Jiangkui, YUAN Hong, YANG Shijie,et al.Dry electrode technology for scalable and flexible high-energy sulfur cathodes in all-solid-state lithium-sulfur batteries[J].Journal of Energy Chemistry,2022,71:612-618. |
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