Global ETD Search

191	Étude des mécanismes et modélisation du vieillissement des batteries lithium-ion dans le cadre d’un usage automobile / Study of mechanisms and modeling of lithium-ion battery ageing for an automotive usage Badey, Quentin 22 March 2012 (has links) Ce travail vise à modéliser le vieillissement des batteries lithium-ion soumises à des sollicitations de type véhicule (électrique ou hybride). Cette étude a notamment pour but d’optimiser le dimensionnement des packs batteries pour véhicule et les stratégies de gestion électrique. Une approche originale, de type fatigue mécanique, a été sélectionnée car potentiellement capable de modéliser des sollicitations complexes et variées. Cette approche a été développée pour une batterie lithium-ion spécifique graphite/NCA. Il apparaît qu’un simple cumul de dommage n’est pas entièrement pertinent et que deux contributions au vieillissement sont à l’œuvre : l’une en fonction de la charge échangée et l’autre en fonction du temps. De multiples essais de vieillissement ont été effectués et montrent l’influence très importante de la température, du courant et de l’état de charge sur chacune de ces contributions. Ces essais permettent de mettre en équation l’impact de chacun de ces paramètres sur la vitesse de dégradation. Il en découle un modèle informatique de prévision du vieillissement, capable de prendre en compte les périodes d’arrêt comme de roulage. Les résultats, sur des sollicitations peu à moyennement complexes, donnent une très faible erreur au niveau de la prévision. Des analyses post-mortem ont également été effectuées sur les batteries étudiées afin de comprendre les mécanismes en jeu. Plusieurs analyses (physico-chimiques et électrochimiques, par spectroscopie d’impédance) permettent de relier les principaux mécanismes de vieillissement à chacune des deux contributions : une altération de la structure cristalline du matériau actif d’électrode positive pour la contribution fatigue, la passivation du matériau actif d’électrode négative pour la contribution temporelle. Ces analyses apportent une vision plus complète du vieillissement et justifient les hypothèses effectuées lors de la mise en place du modèle. Elles permettent également d’envisager une généralisation du modèle à d’autres technologies de batteries lithium-ion. D’ailleurs, un essai de généralisation à une autre batterie commerciale a permis de vérifier la fiabilité et de détecter les limites de notre approche. / This scientific piece of work aims at modeling the aging of lithium-ion batteries, depending on the vehicle stress (electric or hybrid type). More specifically, this study intends to optimise the design of battery packs for vehicle and power management strategies. A original mechanical fatigue approach has been selected as potentially able to model complex and varied demands. This approach was developed for a specific graphite / NCA lithium-ion battery. It appears that a simple damage accumulation is not entirely relevant, and that two contributions to aging are ongoing: one based on charge throughput and the other based on time. Multiple aging tests were performed and have shown the important influence of temperature, current power and state of charge for each contribution. They led to the establishment of equations linking each of these parameters to battery degradation rate. Thanks to these equations, a computer model for aging prevision has been built, able to take into account both cycling and calendar ageing. The model gives, for slightly to moderately complex solicitations, a very small predicting error. Postmortem analyses were also performed on the batteries to understand the mechanisms involved. Several analytical techniques (physicochemical and electrochemical, impedance spectroscopy) make possible to connect the main mechanisms of ageing to the contributions: an alteration of the crystalline structure of the positive electrode active material for the fatigue contribution, passivation of the negative electrode active material for the time contribution. These analyses provide a more complete view of aging and justify the hypothesis made during the implementation of the model. These electrochemical results allow us to consider a generalisation to other lithium-ion battery technologies. Indeed, an attempt to generalise the model to another commercial battery has made possible to check the reliability and to detect limits of this approach. Stockage d’énergie Batterie lithium-ion Véhicule électrique Électrification Vieillissement Approche fatigue Modélisation Energy storage Lithium-ion battery Electric vehicle Electrification Ageing Fatigue approach Model
192	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 (has links) 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
193	Modification des propriétés de conduction ionique d'électrolytes pérovskites à base de lithium par substitution Groleau, Laurence 12 1900 (has links) No description available. Électrochimie Batterie aux ions lithium Électrolyte solide Pérovskite DRX Conduction ionique Electrochemistry Lithium-ion battery Solid electrolytes Perovskite XRD Ionic conductivity
194	Entwicklung und Synthese von Materialien für Polyelektrolytmembranen mit ionischen Flüssigkeiten zum Einsatz in Lithium-Ionen-Batterien / Development and synthesis of materials for poly electrolyte membranes with ionic liquids for application in Lithium-ion batteries Grothe, Dorian C. January 2012 (has links) Für den Einsatz in Autobatterien gibt es besondere Anforderungen an den Elektrolyten im Bereich der Energie- und Leistungsdichten, um beispielsweise thermische Verluste gering zu halten. Hochleitfähige Elektrolyte mit Leitfähigkeiten im Millisiemensbereich sind hier ebenso notwendig wie auch sichere, d.h. möglichst nicht brennbare und einen niedrigen Dampfdruck besitzende Materialien. Um diese Vorgaben zu erreichen, ist es notwendig, einen polymeren Separator zu entwickeln, welcher auf brennbare organische Lösungsmittel verzichtet und damit eine drastische Steigerung der Sicherheit gewährleistet. Gleichzeitig müssen hierbei die Leistungsvorgaben bezüglich der Leitfähigkeit erfüllt werden. Zu diesem Zweck wurde ein Konzept basierend auf der Kombination von einer polymeren sauerstoffreichen Matrix und einer ionischen Flüssigkeit entwickelt und verifiziert. Dabei wurden folgende Erkenntnisse gewonnen: 1. Es wurden neuartige diacrylierte sauerstoffreiche Matrixkomponenten mit vielen Carbonylfunktionen, für eine gute Lithiumleitfähigkeit, synthetisiert. 2. Es wurden mehrere neue ionische Flüssigkeiten sowohl auf Imidazolbasis als auch auf Ammoniumbasis synthetisiert und charakterisiert. 3. Die Einflüsse der Kationenstruktur und der Einfluss der Gegenionen im Bezug auf Schmelzpunkte und Leitfähigkeiten wurden untersucht. 4. Aus den entwickelten Materialien wurden Blendsysteme hergestellt und mittels Impedanzspektrometrie untersucht: Leitfähigkeiten von 10-4S/cm bei Raumtemperatur sind realisierbar. 5. Die Blendsysteme wurden auf ihre thermische Stabilität hin untersucht: Stabilitäten bis 250°C sind erreichbar. Dabei wird keine kristalline Struktur beobachtet. / Within the field of energy storage and charge transfer, the lithium polymer batteries are one of the leading technologies, due to their low manufacture cost and their possible variety of packaging shapes. Despite their good thermal stability and very good weight to energy ratio, lithium ion batteries use as a electrolyte system a mixture of ethylene carbonate and diethyl carbonate as solvent which have a high risk of deflagration when they come in contact with water. Thus the developement of new materials for lithium-ion-batteries are necessary. For the electrolyte there are special requirements in terms of energy- and power density e.g. in order to minimize thermal loss. High conductivity electrolytes with conductivities in the range of milisiemens are as essential as safe materials, like non flammable non-volatile materials. To fulfill these requirements it is important to develop a polymeric lithium ion conductor, which is free of flammable organic solvents in order to ensure safety. Simultaneously it is also ,mandatory to achieve high performances in terms of ion-conductivity. Therefore a concept based on a combination of an oxygen rich polymeric matrix and ionic liquids was developed and verified. Following results were achieved . 1. Synthesis of new diacryalted oxygen rich matrix components with many carbonylfunctions for a good lithium ion transport. 2. Synthesis and characterization of new ionic liquids based on imidazol or ammonium compounds. 3. Investigation of the influences of the cation structure and counter ions for melting points and ion conductivity. 4. Creation of Blendsystems with the developed materials 5. Thermal investigations of these solid-state-electrolytes with DSC and TGA measurements, resulting in thermal stabilities up to 250°C.No crystallization were observed. 6. investigation of these solid-state-electrolytes via AC-impedance spectrometry, resulting in conductivities of 10-4S/cm at room temperature. Lithium-Ionen-Batterie ionische Flüssigkeiten Festelektrolyten AC Impedanz Lithium ion battery ionic liquids solid-state-electrolyte AC -Impedance Chemistry and allied sciences
195	Mathematical Models for Investigation of Performance, Safety, and Aging in Lithium-Ion Batteries Zavalis, Tommy Georgios January 2013 (has links) Rechargeable lithium-ion batteries have both the power and energy capabilities to be utilized in hybrid electric vehicles and other power demanding applications. However, there are obstacles primarily related to reliability in safety and lifetime. Additionally, there is still room for improvement in the battery performance. In this work, physics-based mathematical models have been successfully set-up and numerically solved to investigate performance, safety, and aging in lithium-ion battery systems. This modeling approach enabled a detailed analysis of the electrochemical processes related to these issues. As the models included many parameters and spatial resolution of several variables with time or frequency, strategies for investigation needed to be developed for most of the work. The accuracy of the investigation was consolidated by the utilization of parameters characterized from experimental work. The performance expressed in terms of polarization was determined for a power-optimized battery cell undergoing various operating conditions. A methodology that separated and quantified the contribution of each process to the polarization was set up, allowing the study of the contributions as a snapshot in time and as an average over a cycle. Mass transport in electrolyte was shown to be a crucial feature to improve especially if the battery is expected to undergo high current-loads for long periods of time. Safety-concerns when a battery cell is short-circuited were investigated for three types of short-circuit scenarios. All scenarios raised the temperature to the point where exothermic side reactions were initiated. The similarities between the scenarios in temperature increase were a result of the limiting current being reached. The differences, however small, were related to the placement of the short-circuit. Especially when the current collectors were not directly connected by the short circuit, an increased electronic resistance was observed which lowered both the generated current and heat. The aging of a battery cell was investigated by model analysis of electrodes harvested from fresh and aged cells. A methodology was used where a frequency-dependent model was fitted to three-electrode impedance experiments by tuning parameters associated to electrode degradation. For cycled cells, electrolyte decomposition products inhibiting the mass transport in the electrolyte and particle cracking in the positive electrode increased the impedance. A similar model was also set up for investigation of the lithium intercalation processes in PAN-based carbon fibers, showing it to have both good mass transport and kinetic capabilities. / Laddningsbara litiumjonbatterier har både ur energi- och effektsynpunkt möjligheten att kunna användas i elhybridfordon och inom andra effektkrävande tillämpningsområden. Batteriets säkerhet och livslängd är dock inte helt tillförlitliga. Dessutom finns det fortfarande utrymme för förbättringar av litiumjonbatteriets prestanda. I det här arbetet har matematiska modeller baserade på fysikaliska egenskaper framgångsrikt ställts upp och lösts numeriskt för att studera prestandan, säkerheten samt åldrandet hos litiumjonbatterisystem. Denna typ av modellering gjorde det möjligt att detaljerat analysera hur de elektrokemiska processerna bidrar. Eftersom modellerna omfattade ett stort antal parametrar och har variabler som förändras i åtminstone en dimension med tid eller frekvens, krävdes det att tydliga strategier för arbetet ställdes upp. Modelleringsstudiens noggrannhet stärktes av att flertalet av de använda parametrarna hade bestämts experimentellt. Polarisationen som ett mått på prestanda bestämdes för ett effektoptimerat batteri under olika laster. En metodik som separerar och beräknar hur mycket varje process bidrar till polarisationen skapades och användes för att studera bidragen över tid eller över en hel lastcykel. Resultaten visade att masstransporten i elektrolyten påverkar till stor del och bör förbättras om batteriet förväntas belastas med hög ström under lång tid. Säkerheten i samband med kortslutning av en battericell undersöktes för tre olika fall av kortslutningar. Alla fall uppvisade en temperaturökning som skulle kunna bidra till att exoterma reaktioner startas och termisk rusning uppstår. Temperaturökningen var liknande i samtliga kortslutningsfall och berodde på att gränsströmmen nåddes inom cellen. Skillnaderna mellan kortslutningsfallen var inte så betydande men kunde härledas till kortslutningens placering. Framförallt fallet då strömtilledarna inte kontakterades av kortslutningen observerades en ökad elektronisk resistans som sänkte både strömmen och värmeproduktionen. Åldringen i en battericell undersöktes genom modellanalys av elektroder som tagits från nya eller åldrade celler. Som metod användes en frekvensberoende modell som anpassades till tre-elektrod-impedansmätningar genom förändring av parametrar som beskriver elektrodnedbrytning. Då cellerna cyklats, visade förändringen av dessa parametrar att impedansen ökar på grund av nedbrytningsprodukter från elektrolyten som hindrar masstransporten och att det aktiva materialet i positiva elektroden spricker. En liknande modell användes också till att undersöka PAN-baserade kolfibrers förmåga att interkalera litium och resultaten visade på att den har mycket goda elektrokemiska egenskaper. / <p>QC 20130520</p> lithium-ion battery modeling electrochemical processes impedance polarization performance safety aging power optimized battery litiumjonbatteri modellering elektrokemiska processer impedans polarisation prestanda säkerhet åldring effektoptimerat batteri
196	Design of a State of Charge (SOC) Estimation Block for a Battery Management System (BMS). / Entwicklung eines Ladezustand Block für Battery Management System (BMS) Cheema, Umer Ali January 2013 (has links) Battery Management System (BMS) is an essential part in battery powered applications where large battery packs are in use. BMS ensures protection, controlling, supervision and accurate state estimation of battery pack to provide efficient energy management. However the particular application determines the accuracy and requirements of BMS where it has to implement; in electric vehicles (EVs) accuracy cannot be compromised. The software part of BMS estimates the states of the battery pack and takes the best possible decision. In EVs one of the key tasks of BMS’s software part is to provide the actual state of charge (SOC), which represents a crucial parameter to be determined, especially in lithium iron phosphate (LiFePO4) batteries, due to the presence of the high hysteresis behavior in the open circuit voltage than other kind of lithium batteries. This hysteresis phenomena appears with two different voltage curves during the charging and discharging process. The value of the voltage that the battery is going to assume during the off-loading operation depends on several factors, such as temperature, loop direction and ageing. In this research work, hybrid method is implemented in which advantages of several methods are achieved by implementing one technique combined with another. In this work SOC is calculated from coulomb counting method and in order to correct the error of SOC, an hysteresis model is developed and used due to presence of hysteresis effect in LiFePO4 batteries. An hysteresis model of the open circuit voltage (OCV) for a LiFePO4 cell is developed and implemented in MATLAB/Simulink© in order to reproduce the voltage response of the battery when no current from the cell is required (no load condition). Then the difference of estimated voltage and measured voltage is taken in order to correct the error of SOC calculated from coulomb counting or current integration method. To develop the hysteresis model which can reproduce the same voltage behavior, lot of experiments have been carried out practically in order to see the hysteresis voltage response and to see that how voltage curve change with the variation of temperature, ageing and loop direction. At the end model is validated with different driving profiles at different ambient temperatures. LiFePO4 battery hysteresis model state of charge open circuit voltage empirical modeling Lithium-ion battery OCV hysteresis hysteresis loop hybrid electric vehicle battery management system SOC estimation battery hysteresis
197	U.S. Governmental incentives and policies for investment in electric vehicles and infrastructure Zeeshan, Jafer January 2014 (has links) The purpose of study is to research the development of electric vehicle technology in the United States. This study describes the United States public policies towards electric vehicle technology and system of innovation approaches. The government roles with the help of national system of innovation have been also covered in this study. The point of departure was the study of available literature and U.S energy policy acts which illustrates that the break-through in electric vehicles still not only depended on better battery technology and infrastructure for charging stations but also on social, economic and political factors. The important actors involved in the process are both at local and international level are private firms, governmental departments, research and development (R&D) institutes, nongovernment organizations (NGO’s) and environmental organizations etc. The arguments which are put forward in the background of development of such technologies are to reduce dependence on foreign oil and to reduce emissions of harmful gasses. Transportation system of innovation national system of innovation electric vehicles plug-in hybrid electric vehicles renewable fuels research and battery development lithium-ion battery environment and sustainability
198	State and parameter estimation of physics-based lithium-ion battery models Bizeray, Adrien January 2016 (has links) This thesis investigates novel algorithms for enabling the use of first-principle electrochemical models for battery monitoring and control in advanced battery management systems (BMSs). Specifically, the fast solution and state estimation of a high-fidelity spatially resolved thermal-electrochemical lithium-ion battery model commonly referred to as the pseudo two-dimensional (P2D) model are investigated. The partial-differential algebraic equations (PDAEs) constituting the model are spatially discretised using Chebyshev orthogonal collocation enabling fast and accurate simulations up to high C-rates. This implementation of the P2D model is then used in combination with an extended Kalman filter (EKF) algorithm modified for differential-algebraic equations (DAEs) to estimate the states of the model, e.g. lithium concentrations, overpotential. The state estimation algorithm is able to rapidly recover the model states from current, voltage and temperature measurements. Results show that the error on the state estimate falls below 1% in less than 200s despite a 30% error on battery initial state-of-charge (SoC) and additive measurement noise with 10mV and 0.5°C standard deviations. The parameter accuracy of such first-principle models is of utmost importance for the trustworthy estimation of internal battery electrochemical states. Therefore, the identifiability of the simpler single particle (SP) electrochemical model is investigated both in principle and in practice. Grouping parameters and partially non-dimensionalising the SP model equations in order to understand the maximum expected degrees of freedom in the problem reveals that there are only six unique parameters in the SP model. The structural identifiability is then examined by asking whether the transfer function of the linearised SP model is unique. It is found that the model is unique provided that the electrode open circuit voltage curves have a non-zero gradient, the parameters are ordered, and that the behaviour of the kinetics of each electrode is lumped together into a single parameter which is the charge transfer resistance. The practical estimation of the SP model parameters from frequency-domain experimental data obtained by electrochemical impedance spectroscopy (EIS) is then investigated and shows that estimation at a single SoC is insufficient to obtain satisfactory results and EIS data at multiple SoCs must be combined.
199	Apport de la spectrométrie de masse en temps réel à l’étude de la dégradation thermique d’électrolytes de batteries lithium-ion au contact de matériaux d’électrode positive / Contribution of real-time mass spectrometry to the study of the thermal degradation of lithium-ion battery electrolytes in contact with positive electrode materials Gaulupeau, Bertrand 11 July 2017 (has links) L’utilisation des batteries lithium-ion est dorénavant une technologie de choix pour le secteur automobile notamment pour son utilisation dans les véhicules hybrides et électriques, du fait d’une importante densité d’énergie disponible ainsi que d’une forte densité de puissance nécessaire à la traction d’un véhicule. Cependant, à cause de l’importante énergie embarquée, la sécurité de tels dispositifs doit être renforcée. Il a été rapporté qu’en conditions abusives de température, l’effet cumulé de la dégradation d’un électrolyte utilisant le sel LiPF6 et l’effet catalytique de matériaux d’électrode positive mène à la formation d’espèces organo-fluorées telles que le 2-fluoroéthanol. Ce projet de thèse vise alors à approfondir la compréhension du rôle des matériaux d’électrode positive vis-à-vis de la dégradation d’électrolyte à base de LiPF6, notamment en étudiant la nature des gaz produits en conditions abusives de température. Pour mener à bien ce projet, un dispositif permettant une analyse in situ des gaz formés a été développé. Le rôle de l’eau sur la formation des espèces organo-fluorées fait également l’objet d’une attention toute particulière. L’influence de plusieurs matériaux d’électrode positive sur la nature des produits de dégradation de l’électrolyte a pu être mise en évidence. Ce travail a ainsi permis d’évaluer l’influence de différents paramètres sur la dégradation thermique de l’électrolyte en vue de prédire le choix des différents constituants d’une batterie lithium-ion / The use of lithium-ion batteries is now a technology of choice for the automotive sector especially for its use in hybrid and electric vehicles, due to a high density of energy available as well as a high power density necessary to the traction of a vehicle. However, due to the high on-board energy, the safety of such devices must be enhanced. It has been reported that under abusive thermal conditions the cumulative effect of degradation of a LiPF6-based electrolyte and the catalytic effect of positive electrode materials leads to the formation of fluoro-organic species such as 2-fluoroethanol. This thesis aims to deepen the understanding of the role of positive electrode materials towards the degradation of LiPF6-based electrolyte, in particular by studying the nature of the gases produced under abusive thermal conditions. To carry out this project, a device allowing an in situ analysis of the formed gases has been developed. The role of water on the formation of fluoro-organic species is also the subject of a particular attention. The influence of several positive electrode materials on the nature of the degradation products of the electrolyte has been demonstrated. This work allowed to evaluate the influence of different parameters on the thermal degradation of the electrolyte in order to predict the choice of the various constituents of a lithium-ion battery Batterie lithium-ion Électrolyte Électrode positive Sécurité Spectrométrie de masse Lithium-ion battery Electrolyte Positive electrode Safety Mass spectrometry 541.372 621.312 424
200	Électrodes négatives composites à base d'étain ou de silicium pour accumulateur lithium-ion avec accrochage souple et/ou enrobage à mémoire de forme / Tin- or silicon-based negative electrode composites for lithium-ion battery with floppy pinning and/or memory shape coating Ladam, Alix 08 December 2016 (has links) Ce mémoire est consacré à l’étude de nouveaux composites à base de Ni/Ti/Sn/Si comme matériaux d’électrodes négatives pour accumulateurs rechargeables Li-ion. Ces matériaux se présentent sous la forme d’une matrice active ou inactive électrochimiquement, enrichie avec du silicium pour former un composite nanostructuré. Ils présentent des capacités massiques supérieures à celles du carbone avec de bonnes performances en terme de capacité réversible, stabilité électrochimique, et cinétique de réaction. La mécanosynthèse a été choisie comme méthode d’élaboration de ces composites. Les propriétés physico-chimiques des composites ainsi synthétisés ont été caractérisées par diffraction des Rayons X, spectrométrie Mössbauer de 119Sn et microscopie électronique à balayage. Les caractérisations électrochimiques ont été effectuées par cyclages galvanostatiques. La complémentarité entre ces différentes techniques a permis d’analyser les mécanismes réactionnels. L’étude détaillée de ces nouveaux matériaux composites, nous a permis de mettre en évidence l’influence de la matrice et du taux d’enrichissement en silicium sur les performances électrochimiques (capacité réversible pouvant atteindre 1300 mAh.g¡1 et efficacité coulombique >99,5%). Ces matériaux présentent une grande flexibilité de composition permettant d’adapter leur capacité massique aux applications visées. / This work has been devoted to new Ni/Ti/Sn/Si based composites as negative electrode materials for lithium-ion batteries. Thesematerials are formed by tin based electrochemically active matrix and/or silicon based electrochemically inactive matrix enriched with silicon. They were obtained by ball milling method leading to nanostructured compositeswith strongly improved electrochemical performances compared to commercially used carbon. This includes reversible capacity, electrochemical stability and reaction kinetics.The composites were characterized by X-ray diffraction, 119Sn Mössbauer spectroscopy and scanning electron microscopy while their electrochemical performances were carried out by galvanostatic cycling. Finally, the reaction mechanisms were elucidated from X-ray diffraction and 119Sn Mössbauer spectroscopy used in operando mode. By combining these results with empirical models, it has been possible to optimize the composition and the synthesis conditions of the composite to improve the electrochemical properties and obtain reversible specific capacity up to 1300 mAh.g-1 with Coulombic efficiency higher than 99.5%. In addition, the composition flexibility of these materials allows to adapt their electrochemical properties to specific applications. Batterie lithium-Ion Électrode négative Silicium Étain Composite Spectrométrie Mössbauer 119Sn Lithium-Ion battery Negative electrode Silicon Tin Composite 119Sn Mössbauer spectrometry

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