Global ETD Search

21	Electrochemical Storage of Lithium in Silicon - Morphological Analysis from the Atomistic Scale to the Macroscale Ronneburg, Arne 26 May 2021 (has links) Die experimentellen Daten können bei Dr. Sebastian Risse, Helmholtz-Zentrum Berlin, eingesehen werden. / Silizium-Elektroden werden aufgrund ihrer um eine Gröÿenordnung höheren Kapazität als mögliches Elektrodenmaterial in Lithium-Ionen-Batterien betrachtet. Diese Kapazität geht jedoch mit einer Volumenausdehnung von bis zu 310 % einher. Dies begünstigt einen schnellen Kapazitätsabfall und ein kontinuierliches Wachstum der SEI-Schicht. Ziel dieser Arbeit ist es daher, die Morphologie-Änderung der Siliziumelektrode während des Lithiierungs-Prozesses besser zu verstehen unter Nutzung von operando-Methoden Im ersten Teil wurde Neutronenreflektometrie (NR) genutzt, um die Morphologie-Änderung auf der Nanometerskala einer Siliziumelektrode zu untersuchen. Das Wachsen/Schrumpfen der lithiierten Zone im Silizium wurde beobachtet. Auf der Oberfläche der Elektrode wächst im delithiierten Zustand eine Grenzschicht, welche die Lithiierung verhindert. Nachdem diese Schicht aufgelöst ist, kann Lithium eingelagert werden. Im zweiten Teil wurde operando Röntgen- Phasenkontrast-Radiographie genutzt. Ein rechteckiges Riss-Gitter wurde dabei im delithiierten Zustand beobachtet, welches sich während der Lithiierung schließt. Dieses Gitter ist entlang der Kristallachsen des Siliziums orientiert. Im nächsten Zyklus entsteht das Gitter am selben Ort wieder, und breitet sich mit steigender Zyklenzahl über die Elektrode aus. Im dritten Teil wurde der Einfluss einer künstlichen Grenzschicht auf die Lithiierung untersucht. Erneut wurde NR genutzt. Die künstliche Schicht verringert das Wachstum der SEI-Schicht, unterdrückt es jedoch nicht komplett. Nach 2 Zyklen ist die Grenzschicht degradiert, und Seitenreaktionen können beobachtet werden. / Silicon electrodes receive great interest as potential electrode material in lithium-based batteries due to their one order of magnitude higher capacity. This is accompanied by a volume expansion of up to 310 %, leading to an accelerated capacity loss of the electrodes. The volume expansion creates mechanical stress, leading to fracturization of the electrode and the continuous growth of the solid-electrolyte-interphase (SEI) layer under the consumption of active material. The aim of this thesis is to investigate the morphological changes of silicon electrodes during lithiation/ delithiation. Especially operando-techniques are well-suited to investigate these morphological changes since they allow us to precisely link structural data and the electrochemical state. The first project uses operando neutron reflectometry (NR) and in-situ electrochemical impedance spectroscopy (EIS) to analyze the morphology change of the silicon surface on the nanometer-scale. The growth and shrinkage of the lithiated layers within the electrode as well as the lithium concentration was determined with this method. An SEI-layer forms on top of the silicon electrode in the delithiated state, which hinders the lithium uptake in the initial part of the subsequent lithiation. The second project analyzes the morphology-change of the electrode on the µm-scale. Here the fracturization of the silicon electrode is investigated by operando X-ray phase-contrast radiography. A rectangular fracturization pattern was observed during the second half of the delithiation, which vanished again during the lithiation. The third project investigates the influence of an artificial coating layer on the lithiation process. Again operando NR was chosen as analysis tool. The artificial coating decreased the formation of the SEI-layer within the first cycles, but did not suppress it completely. However, this layer degraded already in an early stage of cycling, resulting in the occurrence of side reactions afterward. Siliziumelektroden Lithium-Ionen-Batterie operando-Analyse Reflektometrie Impedanzspektroskopie Phasenkontrast-Radiographie silicon electrodes lithium-ion batteries operando-measurements reflectometry impedance spectroscopy phase contrast imaging 530 Physik ddc:530
22	Electrochemical synthesis of organic compounds using CO2 and biomass as feedstock Li, Junnan 05 1900 (has links) Le CO2 et la biomasse sont abondants dans la nature. La conversion de ces deux éléments constitutifs en carburants ou en produits chimiques à valeur ajoutée par des méthodes électrochimiques est essentielle pour atténuer la crise énergétique et réduire la pollution de l'environnement, ainsi que pour atteindre la carbone neutralité. Au cours des dernières décennies, de nombreux efforts ont été consacrés à ce domaine, mais la plupart d'entre eux se concentrent sur la conception de catalyseurs et l'amélioration des performances, et seules quelques recherches se concentrent sur de nouvelles réactions ou sur le mécanisme de ces réactions. Ici, nous développons une série de nouvelles réactions et étudions les mécanismes de ces réactions en utilisant la spectroscopie in situ, les principaux résultats sont les suivants : 1) Les réactions de réduction du furfural ont été menées en utilisant une feuille de Cu électrochimique comme catalyseur, et l'alcool furfural (FA, efficacité faradique, FE : 43,0%) et le 2-méthylfurane (MF, FE : 57,5%) ont été obtenus après électrolyse sous -0,43V (par rapport à l'électrode à hydrogène réversible, RHE). Les effets des différentes facettes du catalyseur sur la sélectivité ont été étudiés, et le Cu (110) produit préférentiellement de l'AF, tandis que les défauts sont les sites actifs pour la formation de MF. La spectroscopie Raman operando a montré que la production de FA et de MF partage le même intermédiaire à l'étape initiale, avec différents sites actifs conduisant aux différentes voies entre les étapes intermédiaires et suivantes et générant différents produits. 2) Des produits de liaison C-N (acétamide et formamide) ont été obtenus par la réaction de réduction du CO2 (CO2RR) avec la combinaison du substrat NH3 et des électrocatalyseurs commerciaux à base de nanoparticules de Cu ou de CuO. Avec l'optimisation, la FE maximale de ces deux produits est de ~10% au total, et la meilleure condition de réaction est 50mg Cu NPs, 1M KOH, avec 0.3M NH3, à -0.78V (vs. RHE) pendant 30 mins. L'IR in situ a montré que la formation de formamide et de formate partage le même intermédiaire, et que la production d'acétamide et d'acétate subit une voie de réaction similaire. 3) L'hydroxyméthanesulfonate (HMS), le sulfoacétate (SA) et le méthanesulfonate (produits de liaison C-S, FE représente 6% au total) ont été obtenus par le couplage CO2RR avec l'ajout de sulfite (SO32-), et des NPs de Cu2O synthétisées par la méthode de chimie humide ont été utilisées comme électrocatalyseurs. Parmi ces trois composés à liaison C-S, le HMS est le principal produit, la FE pouvant atteindre un maximum de 6 %. Le XRD in situ a montré que Cu0 est l'espèce active pour le processus de couplage C-S. Les calculs operando Raman et DFT ont montré que CHOH est l'intermédiaire clé dans la formation de la liaison C-S, et que le couplage entre CHOH et SO32- est l'étape qui détermine le taux. / CO2 and biomass are abundant in nature. Conversion of these two building blocks into fuels or value-added chemicals by electrochemical methods is essential for alleviating the energy crisis and reducing environmental pollution, and achieving carbon neutrality. In the past few decades, much effort has been devoted to this field, but most of this focuses on the design of catalysts and improvement of the performances, and only few research thrusts focus on new reactions or the mechanism of these reactions. Herein, we develop a series of new reactions and investigate the mechanisms of these reactions by using in-situ spectroscopy, the main results are shown as follows: 1) Furfural reduction reactions were conducted by using an electrochemical roughed Cu foil as the catalyst, and furfural alcohol (FA, Faradaic efficiency, FE: 43.0%) and 2-methylfuran (MF, FE: 57.5%) were obtained after electrolysis under -0.43V (vs. reversible hydrogen electrode, RHE). The effects of different facets on the selectivity were investigated, and Cu (110) is preferential to produce FA, while defects are the active sites for the formation of MF. Operando Raman spectrum showed that the production of FA and MF share the same intermediate at the initial stage, with different active sites leading to the pathway differential on the intermediate of the following steps and generating different products. 2) C-N bond products (acetamide and formamide) were obtained by CO2 reduction reaction (CO2RR) with the combination of NH3 reactants and commercial Cu or CuO nanoparticle (NPs) electrocatalysts. The maximum FE of these two products is ~ 10% in total. With optimization, we found a higher pH, thicker catalyst layer, and larger size of cations are beneficial to the production of acetamide. This can be attributed to the higher production of C2 intermediate and further leads to a higher FE of acetamide. In-situ IR showed that the formation of formamide and formate share the same intermediate, and the production of acetamide and acetate undergoes a similar reaction pathway. The mechanism can help to design the new next generation catalyst with a higher efficiency, which is beneficial to the future application of this reaction in chemical industry. Nitrate and nitrite are used instead of ammonia as nitrogen sources to produce C-N bond compounds, which suggests that this reaction provides a new possibility for organic synthesis. In all, this reaction expands the scope of the CO2RR application, and is also good for the development of organic synthesis. 3) Hydroxymethanesulfonate (HMS), sulfoacetate (SA) and methanesulfonate (C-S bond products, FE is 6% in total) were obtained by coupling CO2RR with the addition of sulfite (SO32-), and Cu2O NPs which synthesized by the wet chemistry method were used as electrocatalysts. Among these three C-S bond compounds, HMS is the main product, FE can reach 6% maximum. In-situ XRD showed that Cu0 is the active species for C-S coupling process. Operando Raman and DFT calculation further showed that CHOH is the key intermediate in the C-S bond formation, and the coupling between CHOH and SO32- is the rate-determining step. The discovery of reaction intermediates opens up the possibility of designing highly efficient catalysts, which can promote the application of this reaction in real industries. Also, this reaction provides a new possibility to synthesize C-S bond products, which have the potential to partially replace traditional organic synthetic routes with greener and more sustainable procedures. Réduction du furfural Réaction de Réduction du CO2 Spectroscopie Operando Raman Spectroscopieinfrarouge In Situ Mécanisme Furfural Reduction CO2 Reduction Reaction Operando Raman In-situ infrared Spectroscopy Mechanism Chemistry / Chimie (UMI : 0485)
23	Electrochemical and spectroscopic investigations of carbonate-mediated water oxidation to peroxide Bemana, Hossein 02 1900 (has links) Le développement de technologies électrosynthétiques pour la production de H2O2 est attrayant du point de vue de la durabilité. L’utilisation de dioxyde de carbone et/ou d’espèces carbonatées comme médiateurs dans l’oxydation de l’eau en peroxyde est apparue comme une voie viable pour y parvenir, mais de nombreuses questions demeurent quant au mécanisme qui doit être abordé avant que des systèmes pratiques n’émergent. À cette fin, ce travail combine des méthodes électrochimiques et spectroscopiques pour étudier les voies de reaction possibles et les facteurs influençant l'efficacité de cette réaction. Nos résultats électrochimiques indiquent que le CO32- est l'espèce clé qui subit une oxydation électrochimique, avant de réagir avec l'eau loin de la surface du catalyseur vers la production de H2O2. Grâce à des expériences spectroélectrochimiques infrarouges et Raman, nous avons noté que l'épuisement du CO32- est un facteur clé qui limite la sélectivité du procédé. À son tour, l'application de l'électrolyse pulsée peut augmenter cela, avec un ensemble initial de paramètres optimisés augmentant la sélectivité de 20 % à 27 %. Dans l’ensemble, ces travaux contribuent à ouvrir la voie au développement futur d’un système électrosynthétique H2O2 pratique. / The development of electrosynthetic technologies for H2O2 production is appealing from a sustainability perspective. The use of carbon dioxide and/or carbonate species as mediators in water oxidation to peroxide has emerged as a viable route to do so but still many questions remain about the mechanism that must be addressed before practical systems emerge. To this end, this work combines electrochemical and spectroscopic methods to investigate possible reaction pathways and factors influencing the efficiency of this reaction. Our electrochemical results indicate that CO32- is the key species that undergoes electrochemical oxidation, prior to reacting with water away from the catalyst surface en route to H2O2 production. Through spectroelectrochemical infrared and Raman experiments, we noted that CO32- depletion is a key factor that limits the selectivity of the process. In turn, showed how the application of pulsed electrolysis can augment this, with an initial set of optimized parameters increasing the selectivity from 20% to 27%. In all, this work helps pave the way for future development of practical H2O2 electrosynthetic system. Hydrogen peroxide electrosynthesis water oxidation carbonate operando spectroscopy Peroxyde d'hydrogène électrosynthèse oxydation de l'eau spectroscopie operando
24	Novel in operando characterization methods for advanced lithium-ion batteries Petersburg, Cole Fredrick 11 January 2012 (has links) Currently, automotive batteries use intercalation cathodes such as lithium iron phosphate (LiFePO4) which provide high levels of safety while sacrificing cell voltage and therefore energy density. Lithium transition metal oxide (LiMO2) batteries achieve higher cell voltages at the risk of releasing oxygen gas during charging, which can lead to ignition of the liquid electrolyte. To achieve both safety and high energy density, oxide cathodes must be well characterized under operating conditions. In any intercalation cathode material, the loss of positive lithium ions during charge must be balanced by the loss of negative electrons from the host material. Ideally, the TM ions oxidize to compensate this charge. Alarmingly, the stoichiometry of the latest LiMO2 cathode materials includes more lithium ions than the TM ions can compensate for. Inevitably, peroxide ions or dioxygen gas must form. The former mechanism is vital for lithium-air batteries, while the latter must be avoided. Battery researchers have long sought to completely characterize the intercalation reaction in working batteries. However, the volatile electrolytes employed in batteries are not compatible with vacuum-based characterization techniques, nor are the packaging materials required to contain the liquid. For the first time, a solid state battery (using exposed particles of Li1.17Ni0.25Mn0.58O2) was charged while using soft X-ray absorption spectroscopy to observe the redox trends in nickel, manganese and oxygen. This was combined with innovative hard X-ray absorption spectroscopic studies on the same material to create the most complete picture yet possible of charge compensation. Battery Operando Synchotron NEXAFS EXAFS Charge compensation Lithium batteries Li-ion Lithium ion batteries Cathodes Oxidation
25	Crystal chemistry of vanadium phosphates as positive electrode materials for Li-ion and Na-ion batteries / Cristallochimie de phosphates de vanadium comme électrodes positives pour batteries Li-ion et Na-ion Boivin, Édouard 24 November 2017 (has links) Ce travail de thèse a pour but d'explorer de nouveaux matériaux de type structural Tavorite et de revisiter certains déjà bien connus. Dans un premier temps, les synthèses de compositions ciblées ont été réalisées selon des procédures variées (voies tout solide, hydrothermale, céramique assistée par sol-gel, broyage mécanique) afin de stabiliser d'éventuelles phases métastables et d'ajuster la microstructure impactant fortement les performances électrochimiques de tels matériaux polyanioniques. Ces matériaux ont ensuite été décrits en profondeur, dans leurs états originaux, depuis leurs structures moyennes, grâce aux techniques de diffraction (diffraction des rayons X sur poudres ou sur monocristaux et diffraction des neutrons) jusqu'aux environnements locaux, en utilisant des techniques de spectroscopie (résonance magnétique nucléaire à l'état solide, absorption des rayons X, infra-rouge et Raman). Par la suite, les diagrammes de phases et les processus d'oxydoréduction impliqués pendant l'activité électrochimique des matériaux ont été étudiés grâce à des techniques operando (diffraction et absorption des rayons X). La compréhension des mécanismes impliqués pendant le cyclage permet de mettre en évidence les raisons de leurs limitations électrochimiques : La synthèse de nouveaux matériaux (composition, structure, microstructure) peut maintenant être développée afin de contrepasser ces limitations et de tendre vers de meilleures performances / This PhD work aims at exploring new Tavorite-type materials and at revisiting some of the well-known ones. The syntheses of targeted compositions were firstly performed using various ways (all solid state, hydrothermal, sol-gel assisted ceramic, ball milling) in order to stabilize eventual metastable phases and tune the microstructure impacting strongly the electrochemical performances of such polyanionic compounds. The materials were then described in-depth, at the pristine state, from their average long range structures, thanks to diffraction techniques (powder X-rays, single crystal X-rays and neutrons diffraction), to their local environments, using spectroscopy techniques (solid state Nuclear Magnetic Resonance, X-rays Absorption Spectroscopy, Infra-Red and/or Raman). Thereafter, the phase diagrams and the redox processes involved during electrochemical operation of the materials were investigated thanks to operando techniques (SXRPD and XAS). The in-depth understanding of the mechanisms involved during cycling allows to highlight the reasons of their electrochemical limitations: the synthesis of new materials (composition, structure and microstructure) can now be developed to overcome these limitations and tend toward better performance. Cathode à haut potentiel RMN du solide Vanadyl-type defects Operando SXRPD and XAS New Tavorite phases
26	Real-time Investigation of Catalytic Reaction Mechanisms by Mass Spectrometry and Infrared Spectroscopy Theron, Robin 08 July 2015 (has links) Electrospray ionization mass spectrometry (ESI-MS) has been applied to the realtime study of homogeneous organometallic reactions. ESI-MS as a soft ionization technique is amenable to fragile organometallic complexes, and as a fast and sensitive technique is ideal for detecting low concentration intermediates within reactions. Pressurized sample infusion (PSI) was used for continuous sample infusion into the mass spectrometer, granting the air-free conditions necessary for these reactions to be successful, and resulting in reaction profile data that contains information about the dynamics of speciation of the catalyst. Collision induced dissociation (CID) was used to probe the binding affinities of various bisphosphine ligands as well as in characterizing intermediates in reactions. PSI ESI-MS was applied to the hydroboration reaction of the alkene tert-butylethene using the amine-borane H3B⋅NMe3 catalyzed by [Rh(xantphos)]+ fragments to show how the reaction progresses from substrates to products. PSI ESI-MS was also applied to the hydrogenation of a charge-tagged alkyne [Ph3P(CH2)4C2H]+[PF6]-, catalyzed by a cationic rhodium complex [Rh(PcPr3)2(η6-FPh)]+[B{3,5-(CF3)2C6H3}4]– (PcPr3 = triscyclopropylphosphine, FPh = fluorobenzene). This work demonstrated the use of ESI-MS in conjunction with NMR, kinetic isotope effects and numerical modeling for determining a mechanism of reaction. The hydroacylation reaction of a β–S substituted aldehyde and an alkyne catalyzed by [Rh(PiPr2NMePiPr2)(η6-FPh)]+[B{3,5-(CF3)2C6H3}4]– (PiPr2 = diisopropylphosphine) was studied by PSI ESI-MS while employing charged tags, allowing for observation of reaction progress and some key intermediates. A new concept for mechanistic analysis has been developed: coupling of an orthogonal spectroscopic technique with PSI ESI-MS. This new method was applied to the same hydroacylation reaction studied with charged tags. The use of IR in conjunction with ESI-MS led to rate information about the overall reaction along with dynamic information about catalytic speciation. Coupling of these techniques allows for detection over many magnitudes of concentration. / Graduate Mass spectormetry Infrared spectroscopy Catalysis Chemistry operando spectroscopy hydroacylation hydrogenation hydroboration
27	Mechanistic insight into homogeneous catalytic reactions by ESI-MS Ahmadi, Zohrab 28 August 2013 (has links) For the study of homogeneous catalytic reaction mechanisms, the ideal technique would be capable of identifying and measuring in real time the abundances of all components of the reaction mixture, including reactants, products, byproducts, intermediates, and catalyst resting states. This thesis details the development of methodologies designed to transform electrospray ionization mass spectrometry into just such a tool. Species of interests must be charged otherwise invisible in ESI-MS. Therefore, charge-tagged aryl iodide ([4-I-C6H4CH2PPh3]+[Br]-) and a terminal alkyne ([para-(HCC)C6H4CH2PPh3]+[Br]-) were synthesized as the ESI-active substrates for the homogeneous catalysis study. A method named PSI (pressurized sample infusion) was developed to introduce the air and moisture sensitive reaction mixtures to the ESI-MS. The analytical aspects of the method were investigated and optimized. Applicability of the technique was demonstrated through several organic and organometallic mechanism investigations. The above developments were employed to the detailed study of the copper-free Sonogashira (Heck alkynylation) reaction and the hydrodehalogenation of the charged-tag aryl iodide. Simultaneous monitoring of the charged substrate, products and intermediates in the copper-free Sonogashira reaction by PSI-ESI-MS provided rich information about the kinetic and mechanism of this reaction. Kinetic isotope effect study shows a remarkable inverse kinetic isotope effect which is completely unexpected. Numerical models were constructed to simulate the mechanistic observation and to extract the rate constant of each step in the proposed mechanism cycle. The same methodology (PSI technique) was used to the study of the hydrodehalogenation reaction. Key intermediates were detected under the typical reaction conditions. Kinetic isotope effect study was performed in CH3OD and CD3OD. A primary KIE was observed in both deuterated solvents. A revised mechanism cycle was suggested for this reaction based on KIE results, numerical modelling and other experiments. In the proposed cycle deprotonation of methanol occurs on the palladium metal centre instead of the conventional in solution deprotonation (off metal deprotonation). The mechanism of the ligand substitution of charged-tag of a palladium aryl iodide [Pd(TMEDA)(Ar)(I)]+ (Ar = [C6H4CH2PPh3]+[PF6]-) complex against PPh3 was studied in methanol by PSI-ESI-MS. Results revealed that the pathway proceeds quite differently to what had been assumed by others; there was a very fast displacement of [I]– by PPh3 to form [Pd(TMEDA)(Ar)(PPh3)]2+ , followed by a much slower displacement of TMEDA and recoordination of [I]– to form the product [Pd(PPh3)2ArI]+. We successfully integrated UV/Vis spectroscopy, as a complementary method with ESI-MS to shed light into the systems where ESI-MS only is unable to provide a full assignment to homogenous catalysis. The combination of the two fast and sensitive techniques provides a unique opportunity to study the composition of the organometallic reaction mixtures over time. / Graduate / 0486 / zohrabahmadi@gmail.com ESI-MS Homogeneous catalysis operando simultaneous numerical modelling spectroscopy organometallic analytical chemistry inorganic catalysis
28	Development and Application of Operando TEM to a Ruthenium Catalyst for CO Oxidation January 2016 (has links) abstract: Operando transmission electron microscopy (TEM) is an extension of in-situ TEM in which the performance of the material being observed is measured simultaneously. This is of great value, since structure-performance relationships lie at the heart of materials science. For catalyst materials, like the SiO2-supported Ru nanoparticles studied, the important performance metric, catalyst activity, is measured inside the microscope by determining the gas composition during imaging. This is accomplished by acquisition of electron energy loss spectra (EELS) of the gas in the environmental TEM while catalysis is taking place. In this work, automated methods for rapidly quantifying low-loss and core-loss EELS of gases were developed. A new sample preparation method was also established to increase catalytic conversion inside a differentially-pumped environmental TEM, and the maximum CO conversion observed was about 80%. A system for mixing gases and delivering them to the environmental TEM was designed and built, and a method for locating and imaging nanoparticles in zone axis orientations while minimizing electron dose rate was determined. After atomic resolution images of Ru nanoparticles observed during CO oxidation were obtained, the shape and surface structures of these particles was investigated. A Wulff model structure for Ru particles was compared to experimental images both by manually rotating the model, and by automatically determining a matching orientation using cross-correlation of shape signatures. From this analysis, it was determined that most Ru particles are close to Wulff-shaped during CO oxidation. While thick oxide layers were not observed to form on Ru during CO oxidation, thin RuO2 layers on the surface of Ru nanoparticles were imaged with atomic resolution for the first time. The activity of these layers is discussed in the context of the literature on the subject, which has thus far been inconclusive. We conclude that disordered oxidized ruthenium, rather than crystalline RuO2 is the most active species. / Dissertation/Thesis / Doctoral Dissertation Materials Science and Engineering 2016 Materials Science Nanoscience Catalysis EELS In-Situ Operando TEM Ruthenium Transmission Electron Microscopy
29	Study and improvement of non-aqueous Lithium-Air batteries via the development of a silicon-based anode / Etude et amélioration des batteries Lithium-Air via l’optimisation de l’électrode négative avec des alliages de silicium Lepoivre, Florent 15 November 2016 (has links) Face aux défis du XXIème siècle concernant l'approvisionnement mondial en énergie et le réchauffement climatique, il est capital de développer des systèmes de stockage d'énergie efficaces et compétitifs. Parmi eux, la technologie Lithium-Air fait l'objet de nombreuses recherches car elle présente une densité d'énergie théorique dix fois supérieure à celle des batteries Li-ion actuellement utilisées, mais la complexité des réactions chimiques mises en jeu la cantonne au stade de la recherche. Afin d'étudier de manière fiable et reproductible les batteries Li-Air, une nouvelle cellule de test électrochimique intégrant un capteur de pression a été développée. Elle permet d'estimer la quantité de réactions parasites associées à une configuration de batterie lors du cyclage à court et long terme (> 1000 h). Une étude comparative des différents électrolytes les plus utilisés a été réalisée, révélant la différence de comportement entre ces différentes espèces ainsi que l'instabilité de l'anode composée de lithium métallique. Nous avons donc abordé le remplacement de l'anode de lithium par une électrode de silicium pré-lithié. En étudiant l'influence de différentes techniques de pré-lithiation sur des électrodes contenant des particules de Si oxydées en surface, un phénomène de réduction de SiO2 en Si a été mis en évidence, apportant ainsi un gain substantiel en capacité. Les électrodes " activées " ont ensuite été utilisées en tant qu'anode dans les cellules complètes LixSi-O2. Après optimisation, la durée de vie obtenue est supérieure à 400 h (> 30 cycles), ce qui est comparable à la littérature actuelle mais toutefois limité par la présence de réactions parasites. / Supplying the world energy demand while reducing the greenhouse gases emissions is one of the biggest challenges of the 21st century; this requires the development of efficient energy storage devices enabling the utilization of renewable energies. Among them, Lithium-Air batteries are very attractive due to their high theoretical energy density – 10 times that of the current Li-ion batteries – but their development is hindered by the complexity of the chemistry at play. In order to understand such chemistry, we designed a new electrochemical test cell that integrates a pressure sensor, thereby enabling an accurate in operando monitoring of the pressure changes during charge/discharge with high reproducibility and sensitivity. Its use is demonstrated by quantifying the parasitic reactions in Li-O2 cells for various electrolytes frequently encountered in the literature. Through this comparative study, we are able to observe the phenomena currently limiting the performances of Li-O2 batteries after a long cycling (> 1000 h), such as parasitic reactions and the instability of the Li anode. To address the later issue, Li was replaced by a prelithiated silicon electrode made of Si particles oxidized in surface. We demonstrated the feasibility of enhancing both their capacity and cycle life via a pre-formatting treatment that triggers the reduction of their SiO2 coating by liberating pure Si metal. The full LixSi-O2 cells using such treated electrodes exhibit performances competing with the best analogous systems reported in the literature (> 30 cycles; more than 400 h of cycling), but the development of practical prototypes still requires to improve the cycle-life. Énergie Batterie Lithium-Air Li-Ion Silicium Mesure de pression in operando Energy Battery Lithium-Air 541.37
30	Chemo-mechanics of Li-ion batteries: in-situ and operando studies Luize Scalco De Vasconcelos (9735527) 15 December 2020 (has links) <div>Electrochemical energy storage devices play an integral role in the energy transition from fossil fuels to renewable. Still, technological breakthroughs are warranted to expand this progress and enable their use where hydrocarbons are still the dominant option. The requirements restricting further adoption of electrochemical devices are related to energy density, hampering costs of raw materials with the increased global demand, and safety in large scale operations. Furthermore, new applications in flexible electronics add new requisites to this list. Pushing these limits involves multidisciplinary efforts where the mechanics are a crucial part.</div><div> </div><div>This thesis explores the mechanical and kinetic behaviors of batteries at the nano to micro-meter scale through operando mechanical and optical characterization during ongoing electrochemical reactions. A unique experimental platform that enables simultaneous nanoindentation and electrochemical testing of active materials is developed. The validity of mechanical testing during operation in the customized liquid cell is systematically addressed. The evolution of the mechanical properties of electrodes as a function of lithium concentration is probed in real-time. This functional dependence between mechanical properties and composition is then used to introduce the concept of mechanics-informed chemical profiling. This new capability enables characterizing transport kinetics in a detailed and quantitative way, including the role of pressure gradients on diffusion. Pairing these experiments with multi-physics modeling led to a new understanding of the mechanisms regulating charging-rate capability and capacity loss in Li-ion batteries. Experiments on composite electrodes showed that liquid electrolytes change the mechanical properties of both conductive matrix and secondary particles. These observations help understand the interactions between the different components of a battery and demonstrate the need for in-situ mechanical characterization capabilities. </div> Mechanical Engineering Chemo-mechanics kinetics li-ion battery nanoindentation operando in-situ multiphysics coupling energy storage electrochemistry

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