Etude de l'effet des sels de lithium de la couche de passivation sur la cyclabilité d'un accumulateur lithium-ion / Effects of lithium sals from the solid electrolyte interphase on cycling ability of lithium-ion batteries

Chrétien, Fabien

28 January 2015

Limiter le vieillissement des accumulateurs lithium-ion est un challenge pour optimiser leur utilisation notamment dans le domaine spatial. La qualité de la couche de passivation (SEI), formée à la surface de l’électrode négative de graphite lors des premiers cycles de vie de la batterie, est déterminante pour ses performances futures. Celle-ci est composée de polymères et de divers sels de lithium dont la dissolution, la précipitation et la migration affectent les performances. Cette étude vise à comprendre l’impact de ces composés sur la cyclabilité et de proposer des solutions à l’effet néfaste de ces sels sur le bon fonctionnement et le vieillissement de l’accumulateur Li-ion. La première partie de ce travail aborde l’impact de divers sels de lithium de la SEI (LiF, Li2CO3, LiOH, LiOCH3, LiOC2H5) sur le comportement en cyclage des accumulateurs. Par la suite, nous avons proposé des solutions pour améliorer le comportement qu’engendre la présence de ces sels sur les performances à travers deux approches. La première concerne l’utilisation de co-solvants complexants de la famille des glymes. La seconde approche consiste à modifier les propriétés interfaciales électrodes/électrolyte par l’ajout d’additifs tensioactifs à l’électrolyte. Les résultats montrent dans les deux cas des améliorations notables de la cyclabilité des dispositifs en demi-pile et en cellule complète. / Limiting the lithium-ion batteries ageing is a challenge to overcome in the field of spatial applications. The quality of the solid electrolyte interfaces (SEI), created at the electrode surface during the first cycles of the battery, is decisive for its future performances. The SEI is composed of polymers and several lithium salts which are able to dissolve, precipitate and migrate in the electrolyte and hence modify the battery performances. This study aims to understand the impact of the dissolution of these compounds on the cell cycling ability and to propose solutions to avoid the harmful effects of these salts on the battery ageing. The first part of this study is devoted to the study of the effect of dissolved SEI lithium salts (LiF, LiOH, Li2O, Li2CO3 , LiOCH3, LiOC2H5) on the cycling ability of half and full cells.In order to improve the battery performances in spite of the presence of these SEI salts in the electrolyte, two solutions have been examined. The first one is to add a co-solvent belonging to the glyme family which is able to form complexes with lithium ions and the second to use a surfactant additive which will modify the interfacial electrode/electrolyte properties. Results show that in both cases an improvement in half-cell or full-cell cycling ability was achieved.

Batterie lithium-ion

Couche de passivation (SEI)

Interfaces sels de lithium

Additifs

Glymes

Tensioactifs

Lithium-ion battery

Solid electrolyte interphase (SEI)

Interfaces

Lithium salts

Additives

Glymes

Surfactants

Organosulphur compounds for electrochemical energy storage applications : supercapacitors and lithium-sulphur batteries / Composés organo-soufrés pour application au stockage électrochimique de l'énergie : supercondensateurs et batteries lithium-soufre

Coadou, Erwan

07 July 2016

Les travaux presentés dans ce manuscrit ont été consacrés à l’étude de composés organo-soufrés comme composants d’électrolyte pour systèmes électrochimiques de stockage d’énergie, en particulier dans les batteries lithium-soufre. Des liquides ioniques originaux, basés sur des cations sulfonium fonctionnalisés par des chaînes de type glyme ont été synthétisés et caractérisés, puis testés en tant qu’électrolytes dans des supercondensateurs symétriques avec électrodes en carbone activé. Il est apparu que l’adaptation de la structure des liquides ioniques à la porosité du carbone activé est d’importance fondamentale pour le développement de systèmes plus performants. L’ étude menée sur les batteries lithium-soufre a permis une meilleure compréhension des mécanismes de fonctionnement d’un système redox soufre/diphenyl disulfure dans des solvants glymes. L’influence des solvants sur les équilibres chimiques entre polysulfures organiques et minéraux et sur le fonctionnement du système a été étudiée. D’après les premiers résultats obtenus, cette stratégie semble particulièrement prometteuse pour améliorer les performances des batteries lithium-soufre. / The work presented in this manuscript concentrates on investigating the use of organosulfur compounds as potential electrolyte components for electrochemical energy storage systems, in particular in lithium-sulfur batteries. Novel glyme-functionalised sulfonium-based ionic liquids were synthesised and characterised before being tested as pure electrolytes for symmetrical supercapacitors based on activated carbon electrodes. The adaptation of the structure of the ionic liquids to the porosity of activated carbon was found to be of fundamental importance for the design of more efficient systems. For lithium-sulfur batteries, the study has enabled a better understanding of the mechanisms involved during the operation of the sulfur/diphenyl disulfide redox couple in a range of glyme-based solvents. Similarly, the influence of the glyme-based solvents on the chemical equilibria between organic and mineral polysulfides and on the system operation has been investigated. The initial results demonstrated that this is a particularly promising strategy in order to significantly improve the performances of lithium-sulfur batteries.

Stockage électrochimique

Liquide ionique

Sulfonium

Glymes

Supercondensateur

Batterie lithiumsoufre

Électrolyte

Polysulfures

Disulfure organique

Electrochemical storage

Ionic liquids

Sulfonium

Glymes

Supercapacitors

Lithium-sulfur battery

Electrolyte

Polysulfides

Organic disulfide

Crystalline polymer and small molecule electrolytes

Ainsworth, David A.

January 2010

The research presented in this thesis includes a detailed investigation into factors influencing ionic conductivity in the crystalline polymer electrolyte PEO₆:LiPF₆. It has previously been shown that preparing PEO₆:LiPF₆ with PEO modified with larger –OC₂H₅ end groups increases ionic conductivity by one order of magnitude [¹],primarily due to disruption of the crystal structure caused by the inclusion of the larger end groups. In this study it is shown that by reducing PEO molecular weight in crystalline PEO₆:LiPF₆ ionic conductivity is also increased. This was attributed to an increasing concentration of polymer chain end regions upon lowering molecular weight resulting in the creation of more defects, as well as possible increases in crystallite size resulting in longer continuous pathways for ion transport. Similar results were observed using both polydispersed and monodispersed PEO to prepare complexes. In addition, it is demonstrated here that ionic conductivity in crystalline polymerelectrolytes is not confined to PEO₆:LiXF₆ (X=P, As, Sb)[²][³] type materials. The structures and ionic conductivity data are reported for a series of new crystalline polymer complexes: the alkali metal electrolytes. They are composed of low molecular weight PEO and different alkali metal hexafluoro salts (Na⁺, K⁺ and Rb⁺), and include the best conductor poly(ethylene oxide)₈:NaAsF₆ discovered to date [⁴], with a conductivity 1.5 orders of magnitude higher than poly(ethylene oxide)₆:LiAsF₆. A new class of solid ion conductor is reported: the crystalline small-molecule electrolytes. Such materials consist of lithium salts dissolved in low molecular weight glyme molecules [CH₃O(CH₂CH₂O)[subscript(n)]CH₃, n=1-12], forming crystalline complexes [⁵][⁶]. These materials are soft solids unlike ceramic electrolytes and unlike polymer electrolytes they are highly crystalline, are of low molecular weight and have no polydispersity. By varying the number of repeat units in the glyme molecule, many complexes may be prepared with a wide variety of structures. Here, ionic conductivity and cation transference number (t₊) data for several such complexes is presented [⁷][⁸][⁹].These complexes have appreciable ionic conductivities for crystalline complexes and their t₊ values vary markedly depending on the glyme molecule utilized. The differences in t₊ values can be directly attributed to differences in their crystal structures. [¹] Staunton, E., Andreev, Y.G. & Bruce, P.G. Factors influencing the conductivity of crystalline polymer electrolytes. Faraday Discussions 134, 143-156 (2007). [²] Gadjourova, Z., Andreev, Y.G., Tunstall, D.P. & Bruce, P.G. Ionic conductivity in crystalline polymer electrolytes. Nature 412, 6846 (2001). [³] Stoeva, Z., Martin-Litas, I., Staunton, I., Andreev, Y.G. & Bruce, B.G. Ionic Conductivity in the Crystalline Polymer Electrolytes PEO₆:LiXF₆, X = P, As, Sb. J. Am. Chem. Soc. 125, 4619-4626(2003). [⁴] Zhang, C., Gamble, S., Ainsworth, D., Slawin, A.M.Z., Andreev, Y.G. & Bruce, P.G. Alkali metal crystalline polymer electrolytes. Nature Materials 8, 580-584 (2009). [⁵] Henderson, W.A., Brooks, N.R., Brennessel, W.W. & Young Jr, V.G. Triglyme-Li⁺ Cation Solvate Structures: Models for Amorphous Concentrated Liquid and Polymer Electrolytes (I). Chem. Mater. 15, 4679-4684 (2003). [⁶] Henderson, W.A., Brooks, N.R. & Young Jr, V.G. Tetraglyme-Li⁺ Cation Solvate Structures: Models for Amorphous Concentrated Liquid and Polymer Electrolytes (II). Chem. Mater. 15, 4685-4690 (2003). [⁷] Zhang, C., Andreev, Y.G. & Bruce, P.G. Crystalline small-molecule electrolytes. Angewandte Chemie, International Edition 46, 2848-2850 (2007). [⁸] Zhang, C., Ainsworth, D., Andreev, Y.G. & Bruce, P.G. Ionic Conductivity in the Solid Glyme Complexes [CH₃O(CH₂CH₂O)[subscript(n)]CH₃]:LiAsF₆ (n = 3,4). J. Am. Chem. Soc. 129, 8700- 8701 (2007). [⁹] Zhang, C., Lilley, S.J., Ainsworth, D., Staunton, E., Andreev, Y.G., Slawin, A.M.Z. & Bruce, P.G. Structure and Conductivity of Small-Molecule Electrolytes [CH₃O(CH₂CH₂O)[subscript(n)]CH₃]:LiAsF₆ (n = 8-12). Chem. Mater. 20, 4039-4044 (2008).

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