Investigation of the reaction mechanism of lithium sulfur batteries in different electrolyte systems by in situ Raman spectroscopy and in situ X-ray diffraction

文献信息

发布日期 2017-03-07
DOI 10.1039/C6SE00104A
影响因子 6.367
作者

W. Zhu, A. Paolella, C.-S. Kim, D. Liu, Z. Feng, C. Gagnon, J. Trottier, A. Vijh, A. Guerfi, A. Mauger, C. M. Julien, M. Armand, K. Zaghib


查看原文

摘要

Lithium–sulfur batteries are of great interest owing to their high theoretical capacity of 1675 mA h g−1 and low cost. Their discharge mechanism is complicated and it is still a controversial issue. In the present work, in situ Raman spectroscopy is employed to investigate the poly-sulfide species in the sulfur cathode and in the electrolyte during the cycling of Li–S batteries. The aim is to understand the discharge mechanism and the influence of the electrolyte on the dissolution of sulfur and poly-sulfides. S8n− is identified as the main species in the high voltage plateau of discharge together with cycloocta S8, in the cell using 0.5 mol L−1 LiTFSI–PY13–FSI as the electrolyte. S42−, S22− and S2− are detected soon after the low voltage plateau is reached. A discharge mechanism in the PY13–FSI is proposed based on the identified species which provides important information for improving and designing cathodes. Electrolytes of 0.5 mol L−1 LiTFSI–PY13–FSI and 1 mol L−1 LiTFSI–DOL–DME are used in studying the dissolution of sulfur and poly-sulfides. The results demonstrate that the same poly-sulfide species are present in the two electrolytes. However, the rates of poly-sulfide formation and diffusion to the anode are slow in the ionic liquid compared to those in the ether-based electrolyte due to different ionic mobilities of various species in the two electrolytes. These differences are evidenced by the observation of poly-sulfide species in the DOL–DME from the very beginning of cell assembly even before starting the discharge whereas their appearances, in the ionic liquid, are delayed and only found at the end of the high voltage plateau. Notably, the soluble elemental sulfur is clearly observed in the ionic liquid electrolyte during the first discharge in the high voltage region, which is very different from the DOL–DME system where the elemental sulfur is quickly reduced to poly-sulfides due to self-discharge reactions. In addition, the elemental sulfur is also detected near the lithium anode in DOL–DME at the end of charge, for the first time to our knowledge, which suggests that the degradation of lithium metal is caused by the multiple reactions of the lithium metal surface with soluble poly-sulfides and/or elemental sulfur.

相关文献

Ring opening copolymerization of ε-caprolactone and diselenic macrolide carbonate for well-defined poly(ester-co-carbonate): kinetic evaluation and ROS/GSH responsiveness

Jiahao Wang, Chuanhao Sun, Jieni Hu, Yanling Huang, Yunxiang Lu, Yan Zhang

2020-01-07 Paper

DOI: 10.1039/C9PY01788G

Inside front cover

Cover

DOI: 10.1039/D0PY90033H

Water-soluble conjugated polymeric micelles as a carrier for studying Pt(iv) release and imaging in living cells

Ting Yang, Jilin Liu, Zhiru Hu, Jie Jiang, Fei Yan, Guodong Feng

2020-01-13 Paper

DOI: 10.1039/C9PY01550G

Effects of solvents, additives, and π-allyl ligand structures on the polymerization behavior of diazoacetates initiated by π-allylPd complexes

Hiroaki Shimomoto, Moemi Nakajima, Akihiro Watanabe, Hirokazu Murakami, Tomomichi Itoh, Eiji Ihara

2020-01-22 Paper

DOI: 10.1039/C9PY01654F

Mesochiral phases from the self-assembly of chiral block copolymers

Kai-Chieh Yang, Po-Ting Chiu, Rong-Ming Ho

2020-01-22 Perspective

DOI: 10.1039/C9PY01797F

Unraveling the kinetics of the structural development during polymerization-induced self-assembly: decoupling the polymerization and the micelle structure

Rintaro Takahashi, Shotaro Miwa, Ji Ha Lee, Shota Fujii, Noboru Ohta, Kazuo Sakurai

2020-01-14 Paper

DOI: 10.1039/C9PY01810G

Natural lignin nanoparticles: a promising nano-crosslinker for constructing fluorescent photoswitchable supramolecular hydrogels

Xue Liu, Shumin Dong, Zhijun Chen, Chao He, Yonghao Zheng

2020-01-28 Paper

DOI: 10.1039/C9PY01845J

Comparison of poly(ethylene glycol)-based networks obtained by cationic ring opening polymerization of neutral and 1,2,3-triazolium diepoxy monomers

Mona M. Obadia, Jannick Duchet-Rumeau, Julien Bernard, Anatoli Serghei, François Tournilhac, Jean-Pierre Pascault, Eric Drockenmuller

2020-01-27 Paper

DOI: 10.1039/C9PY01923E

您可能还喜欢

化合物问答

处理2-异丙基-5-羧基-1,3-二氧六环(CAS号:116193-72-7)时应注意哪些实验室安全事项?

处理2-异丙基-5-羧基-1,3-二氧六环时应注意以下安全事项:1. 戴上防护眼镜和手套,避免直接接触皮肤和眼睛。2. 在通风橱中操作,确保空气流通。3. 防止...

116193-72-72-Isopropyl-1,3-diox...
化合物问答

2-Hydroxy-N,N-dimethyl-2-phenylacetamide(CAS号:2019-71-8)的市场或研究趋势如何?

该化合物在制药和精细化工领域具有一定的应用,特别是在药物合成中作为中间体。随着环保意识的提高,市场对更安全、更环保的化学品的需求增加,因此该化合物的研究趋势倾向...

2019-71-82-Hydroxy-N,N-dimeth...
化合物问答

4-(1H-吡唑-3-基)哌啶(CAS号:278798-08-6)应用于哪些行业?

4-(1H-吡唑-3-基)哌啶在医药领域有潜在应用,可用于合成药物中间体。此外,在聚合物和传感器领域也有一定的应用前景,可以作为功能材料的一部分。

278798-08-64-(1H-Pyrazol-3-yl)p...
化合物问答

什么是三氯噻嗪(CAS号:133-67-5)?

三氯噻嗪是一种化学物质,其英文名称为6-Chloro-3-(dichloromethyl)-3,4-dihydro-2H-1,2,4-benzothiadiaz...

133-67-56-Chloro-3-(dichloro...
化合物问答

阿螺旋霉素(CAS号:467214-20-6)通常如何合成?

阿螺旋霉素的合成通常采用生物发酵技术,首先从特定的链霉菌提取前体物质,然后通过一系列化学修饰步骤,如酰胺化、环化等,最终得到阿螺旋霉素。常用的催化剂包括有机酸等...

467214-20-6Alvespimycin Hydroch...
化合物问答

什么是2-(二甲基氨基)-5-硝基苯甲酸(CAS号:4405-28-1)?

2-(二甲基氨基)-5-硝基苯甲酸是一种化学化合物,其分子式为C9H11N2O4。该化合物具有一定的生物活性和化学性质,常用于医药、农药及研究领域。

4405-28-12-(Dimethylamino)-5-...
化合物问答

1-苯基-1H-吡唑-4-甲酸甲酯(CAS号:7188-96-7)应用于哪些行业?

1-苯基-1H-吡唑-4-甲酸甲酯主要应用于医药行业,用作合成其他药物的中间体。此外,它还可能在聚合物、传感器等领域有应用。

7188-96-7Methyl 1-phenyl-1h-p...
化合物问答

1-(三异丙基甲硅烷基氧基)环丙烷羧酸甲酯(CAS号:83010-83-7)应用于哪些行业?

该化合物主要用于有机合成中间体领域,特别是在医药合成中作为关键中间体。它也可用于聚合物合成和传感器材料制备。由于其特殊的环丙烷结构和甲硅烷基氧基团,它在半导体材...

83010-83-77-Methoxy-8-nitroqui...
化合物问答

(+)-蛇菰宁(CAS号:215319-47-4)安全吗?

目前没有明确的毒性数据,但作为天然化合物,它通常被认为相对安全。然而,在操作时应避免直接接触皮肤和眼睛,并确保良好的通风条件。

215319-47-4Balanophonin, (+)-
化合物问答

如何处理含有对甲苯氧基乙酸肼(CAS号:36304-39-9)的废料?

含有对甲苯氧基乙酸肼的废料应首先通过中和或沉淀等方法进行预处理,以降低其毒性。然后,可以采用焚烧或交由专业废物处理公司进行安全处置。根据当地法规和环境标准,务必...

36304-39-92-(4-Methylphenoxy)a...
免责声明
本页面提供的学术期刊信息仅供参考和研究使用。我们与任何期刊出版商均无关联,也不处理投稿事宜。如有投稿相关咨询,请直接联系相关期刊出版商。
如发现页面信息有误,请发送邮件至 support@chemtradehub.com 联系我们。我们将及时核实并处理您的问题。