Novel High Voltage Electrodes for Li-ion Batteries

Tripathi, Rajesh

January 2013

An alternate family of “high” voltage (where the equilibrium voltage lies between 3.6 V and 4.2 V) polyanion cathode materials is reported in this thesis with the objective of improving specific energy density (Wh/kg) and developing a better understanding of polyanion electrochemistry. The electrochemical properties, synthesis and the structure of novel fluorosulfate materials crystallizing in the tavorite and the triplite type mineral structures are described. These materials display highest discharge voltages reported for any Fe2+/Fe3+ redox couple. LiFeSO4F was prepared in both the tavorite and the triplite polymorphs using inexpensive and scalable methods. Complete structural characterization was performed using X-ray and neutron based diffraction methods. A rapid synthesis of fluorosulfates can be achieved by using microwave heating. The local rapid heating created by the microwaves generates nanocrystalline LiFeSO4F tavorite with defects that induce significant microstrain. To date, this is unique to the microwave synthesis method. Phase transformation to the more stable triplite framework, facilitated by the lattice defects which include hydroxyl groups, is therefore easily triggered. The formation of nanocrystalline tavorite leads to nanocrystalline triplite, which greatly favors its electrochemical performance because of the inherently disordered nature of the triplite structure. Direct synthesis of the electrochemically active triplite type compound can be carried out either by extending the duration of the solvothermal reactions or by the partial substitution of Fe by Mn to produce LiFe1-xMnxSO4F. This study, overall, has led to a better understanding of the transformation of tavorite to the triplite phase. To examine Li and the Na ion conduction and their correlation with the electrochemical performance of 3-D, 2-D and 1-D ion conductors, atomistic scale simulations have been used to investigate tavorite type LiFeSO4F, NaFeSO4F, olivine type NaMPO4 (M= Fe, Mn, Fe0.5Mn0.5) and layered Na2FePO4F. These calculations predict high mobility of the Li-ion in the tavorite type LiFeSO4F but sluggish Na-ion transport in iso-structural NaFeSO4F. High mobility of the Na-ion is predicted for phosphate layered and olivine structures. Finally, the synthesis and structural details of NaMSO4F (M=Fe, Mn) and NH4MSO4F (M=Fe, Mn) are presented in the last chapter to show the structural diversity present in the fluorosulfate family.

Li-ion Batery

Na-ion Battery

Diffraction X-ray, Neutron

Electrochemistry

Atomistic Scale Simulations

Ion conduction

Chemistry

Energy storage properties of iridium oxides : model materials for the study of anionic redox / Propriétés de stockage de l'énergie dans les oxydes d'iridium : matériaux modèles pour l'étude du redox anionique

Perez, Arnaud

19 December 2017

L’amélioration des systèmes de stockage d’énergie représente un défi majeur de la transition vers les véhicules électriques et les énergies renouvelables. Les accumulateurs Li-ion, qui ont déjà conquis le marché de l’électronique portatif, constitueront la technologie dominante pour réaliser cet objectif, et sont donc l’objet d’intense recherches afin d’améliorer leurs performances, en particulier en termes de capacité. Parmi les stratégies les plus prometteuse pour augmenter la capacité des matériaux de cathodes, beaucoup d’espoir est placé dans la préparation de matériaux riches en lithium, qui combinent l’activité électrochimique des cations (métaux de transitions) et des anions (oxygène). Cependant, l’activation des propriétés redox de l’oxygène est accompagnée de plusieurs problèmes qui freinent le développement industriel de ces matériaux. Il est donc nécessaire d’obtenir de solides connaissances fondamentales sur le phénomène de redox anionique pour résoudre ces problèmes. En utilisant des matériaux modèles à base d’iridium, ce travail explore comment l’activité de l’oxygène est influencé par son environnement local. Les propriétés électrochimiques des composés Na2IrO3 et Na(Li1/3Ir2/3)O2 sont étudiés afin de comprendre l’impact de la nature de l’ion alcalin. L’influence du ratio Li/M dans les oxydes de structure NaCl est étudié à travers la synthèse d’un nouveau composé de formule Li3IrO4, qui présente la plus haute capacité réversible parmi les matériaux d’insertion utilisés comme cathode. Cette famille de matériau est finalement étendue à des phases contenant des protons par une simple méthode d’échange cationique, et les propriétés électrochimiques d’un nouveau composé H3+xIrO4 sont étudiées, dévoilant de très bonnes propriétés de stockage de puissance en milieu aqueux. / Improving energy storage stands as a key challenge to facilitate the transition to electric vehicles and renewable energy sources in the next years. Li-ion batteries, which have already conquered the portable electronic market, will be the leading technology to achieve this goal and are therefore the focus of intense research activities to improve their performances, especially in terms of capacity. Among the most promising strategies to obtain high capacity cathode materials, the preparation of Li-rich materials combining the redox activity of cations (transition metals) and anions (oxygen) attracts considerable interest. However, activation of anionic redox in these high capacity materials comes with several issues that need to be solved prior their implementation in the energy storage market. Deep fundamental understanding of anionic redox is therefore required to go forward. Using model systems based on iridium, this work explores how the oxygen local environment can play a role on the activation of anionic redox. The electrochemical properties of Na2IrO3 and Na(Li1/3Ir2/3)O2 phases are studied to understand the impact of the alkali nature. The influence of the Li/M ratio in rocksalt oxides is investigated with the synthesis of a new material Li3IrO4, which presents the highest reversible capacity among intercalation cathode materials. The rich electrochemical properties of this family of iridate materials are finally extended by preparing proton-based materials through a simple ion-exchange reaction and the electrochemical properties of a new H3+xIrO4 material are presented, with high rate capability performances.

Batterie

Li/Na-Ion

Cathode

Oxydes lamellaires

Redox anionique

Iridium

Li-ion batteries

Anionic redox

Iridium

540

Elaboration de nouveaux matériaux à base de sulfates pour l'électrode positive des batteries à ions Li et Na

Reynaud, Marine

09 December 2013

Les prochaines générations de batteries à ions lithium et sodium seront basées sur le développement de nouveaux matériaux d'électrode positive durables, peu chers et sûrs. Dans ce but, nous avons exploré le monde des minéraux à la recherche de structures présentant les pré-requis pour l'insertion et la désinsertion d'ions alcalins. Nous avons alors entrepris l'étude de sulfates bimétalliques dérivés du minéral bloedite, ayant pour formule générale AxM(SO4)2*nH2O (A = Li, Na, M = métal de transition 3d, et n = 0, 4). Ces systèmes présentent une cristallochimie riche, montrant des transitions structurales en fonction de la température ainsi qu'avec le départ des molécules d'eau. Les nouvelles structures ont été déterminées en combinant les techniques de diffraction des rayons X, neutrons et électrons. Nous avons également montré que les composés à base de lithium LixM(SO4)2 présentent des propriétés antiferromagnétiques intéressantes, du fait notamment de leurs structures particulières qui permettent seulement des interactions de super-super-échange. Enfin et surtout, nous avons, parmi les composés isolés, identifié trois sulfates à base de fer, à savoir Na2Fe(SO4)2*4H2O, Na2Fe(SO4)2 et Li2Fe(SO4)2, qui présentent des propriétés électrochimiques intéressantes face au lithium et au sodium. Avec un potentiel de 3,83 V vs. Li+/Li0, la nouvelle phase marinite Li2Fe(SO4)2 affiche le plus haut potentiel jamais observé pour le couple redox FeIII+/FeII+ dans un composé inorganique à base de fer et dépourvu de fluor, et est en fait seulement dépassé par celui de la forme triplite de LiFeSO4F.

[CHIM:MATE] Chimie/Matériaux

Batteries Li-ion

Batteries Na-ion

Electrode positive

Composés polyanioniques

Sulfates

Structures magnétiques

Cathode

Matériaux à hautes performance à base d'oxydes métalliques pour applications de stockage de l'énergie / High performance metal oxides for energy storage applications

Wang, Luyuan Paul

21 July 2017

Le cœur de technologie d'une batterie réside principalement dans les matériaux actifs des électrodes, qui est fondamental pour pouvoir stocker une grande quantité de charge et garantir une bonne durée de vie. Le dioxyde d'étain (SnO₂) a été étudié en tant que matériau d'anode dans les batteries Li-ion (LIB) et Na-ion (NIB), en raison de sa capacité spécifique élevée et sa bonne tenue en régimes de puissance élevés. Cependant, lors du processus de charge/décharge, ce matériau souffre d'une grande expansion volumique qui entraîne une mauvaise cyclabilité, ce qui empêche la mise en oeuvre de SnO₂ dans des accumulateurs commerciaux. Aussi, pour contourner ces problèmes, des solutions pour surmonter les limites de SnO₂ en tant qu'anode dans LIB / NIB seront présentées dans cette thèse. La partie initiale de la thèse est dédié à la production de SnO₂ et de RGO (oxyde de graphène réduit)/SnO₂ par pyrolyse laser puis à sa mise en oeuvre en tant qu'anode. La deuxième partie s'attarde à étudier l'effet du dopage de l'azote sur les performances et permet de démontrer l'effet positif sur le SnO₂ dans les LIB, mais un effet néfaste sur les NIB. La partie finale de la thèse étudie l'effet de l'ingénierie matricielle à travers la production d'un composé ZnSnO₃. Enfin, les résultats obtenus sont comparés avec l'état de l'art et permettent de mettre en perspectives ces travaux. / The heart of battery technology lies primarily in the electrode material, which is fundamental to how much charge can be stored and how long the battery can be cycled. Tin dioxide (SnO₂) has received tremendous attention as an anode material in both Li-ion (LIB) and Na-ion (NIB) batteries, owing to benefits such as high specific capacity and rate capability. However, large volume expansion accompanying charging/discharging process results in poor cycleability that hinders the utilization of SnO₂ in commercial batteries. To this end, engineering solutions to surmount the limitations facing SnO₂ as an anode in LIB/NIB will be presented in this thesis. The initial part of the thesis focuses on producing SnO₂ and rGO (reduced graphene oxide)/SnO₂ through laser pyrolysis and its application as an anode. The following segment studies the effect of nitrogen doping, where it was found to have a positive effect on SnO₂ in LIB, but a detrimental effect in NIB. The final part of the thesis investigates the effect of matrix engineering through the production of a ZnSnO₃ compound. Finally, the obtained results will be compared and to understand the implications that they may possess.

Pyrolyse laser

Batteries au lithium-Ion

Batteries au sodium-Ion

Oxydes métalliques

Laser Pyrolysis

Li ion batteries

Na ion batteries

Metal oxides

620

Les accumulateurs au sodium et sodium-ion, une nouvelle génération d’accumulateurs électrochimiques : synthèse et électrochimie de nouveaux matériaux d’électrodes performants / Sodium batteries and sodium-ion batteries, a new family of rechargeable batteries : synthesis and electrochemistry of new high performance electrode materials

Huynh, Le Thanh Nguyen

31 October 2016

Les accumulateurs au lithium jouent un rôle important comme source d'alimentation pour les appareils électroniques portables en raison de leur forte capacité gravimétrique et volumétrique et leur haute tension. En outre, la technologie lithium-ion est la mieux placée pour une application à grande échelle, telle que le véhicule électrique, ce qui pose un problème de ressource et à terme, de coût. Une des réponses envisagées sur le plan économique et environnemental est le développement d’accumulateurs sodium-ion. Dans tous les cas, le problème scientifique consiste à proposer des matériaux d’insertion des ions sodium avec un caractère réversible de la réaction électrochimique, et une durée de vie compétitive par rapport aux systèmes au lithium. Le travail présenté se situe dans cet effort de recherche. Les potentialités de matériaux dérivés du pentoxyde de vanadium, de structure 2D, sont étudiées comme composés d’intercalation du sodium: le composé de référence V2O5, le bronze performant dérivé de V2O5 de formule K0,5V2O5, ε’-V2O5, ainsi que le composé au manganèse de type lamellaire : la birnessite sol-gel et sa forme dopée au cobalt. Les relations structure-électrochimie sont élucidées à travers une étude combinant propriétés électrochimiques, diffraction des Rayons X et spectroscopie Raman des matériaux à différents taux d’insertion, en fin de réaction et après cyclages galvanostatiques. De nouvelles phases sont obtenues et des capacités spécifiques comprises entre 100 et 160 mAh/g dans le domaine de potentiel 4V-1V peuvent être obtenues avec parfois une stabilité remarquable comme dans le cas de NaV2O5 et ε’-V2O5 / Since commercialization, Li-ion batteries have been playing an important role as power source for portable electronic devices because of high gravimetric, volumetric capacity and high voltage. Furthermore, the lithium-ion technology is best suited for large-scale application, such as electric vehicles, which poses a resource problem and ultimately cost. On the contrary, sodium is a most abundant element, inexpensive and similarly properties as lithium. In order to solve the problem of lithium raw resource, sodium is proposed as a solution for next generation power source storage. This work investigates the potential derivative vanadium pentoxide materials as sodium intercalation compounds: the V2O5 reference compound, the promizing potassium bronze K0,5V2O5, ε'-V2O5, as well as a lamellar manganese oxide: the sol-gel birnessite and its doped cobalt form. The structure-electrochemistry relationships are clarified through a study combining electrochemical properties, X-ray diffraction and Raman spectroscopy of materials at different insertion rate, end of the reaction and after galvanostatic cycling. New phases are highlighted and specific capacities between 100 and 160 mAh / g in the field of 4V-1V potential can be obtained with sometimes remarkably stable as in the case of NaV2O5 and ε'-V2O5

Batterie au sodium

Batteries sodium-Ion

Cinétique électrochimique

Composés d’intercalation

Électrochimie du solide

Spectroscopie Raman

Sodium battery

Na-Ion batteries

Electrochemical kinetics

Intercalation compounds

Solid state electrochemistry

Raman spectroscopy

Pokročilé uhlíkové struktury jako materiál pro Na-ion akumulátory / Advanced carbon structures as a material for Na-ion batteries

Bečan, Jan

January 2021

This diploma thesis deals with the description of individual types of batteries. The first part is focused to primary and secondary batteries, materials for their positive and negative electrodes with a focus on lithium-ion batteries and their changes over time. The next section focuses on a more detailed description of sodium-ion batteries, used electrode materials and to their problems. Practical part is focesed to preparing of electrode materials and to completing of measuring electrochemical cell and to discribing of measuring methodes and to evaluation of measured data.

Colloidal Synthesis and Photophysical Characterization of Group IV Alloy and Group IV-V Semiconductors: Ge1-xSnx and Sn-P Quantum Dots

Tallapally, Venkatesham

01 January 2018

Nanomaterials, typically less than 100 nm size in any direction have gained noteworthy interest from scientific community owing to their significantly different and often improved physical properties compared to their bulk counterparts. Semiconductor nanoparticles (NPs) are of great interest to study their tunable optical properties, primarily as a function of size and shape. Accordingly, there has been a lot of attention paid to synthesize discrete semiconducting nanoparticles, of where Group III-V and II-VI materials have been studied extensively. In contrast, Group IV and Group IV-V based nanocrystals as earth abundant and less-non-toxic semiconductors have not been studied thoroughly. From the class of Group IV, Ge1-xSnx alloys are prime candidates for the fabrication of Si-compatible applications in the field of electronic and photonic devices, transistors, and charge storage devices. In addition, Ge1-xSnx alloys are potentials candidates for bio-sensing applications as alternative to toxic materials. Tin phosphides, a class of Group IV-V materials with their promising applications in thermoelectric, photocatalytic, and charge storage devices. However, both aforementioned semiconductors have not been studied thoroughly for their full potential in visible (Vis) to near infrared (NIR) optoelectronic applications. In this dissertation research, we have successfully developed unique synthetic strategies to produce Ge1-xSnx alloy quantum dots (QDs) and tin phosphide (Sn3P4, SnP, and Sn4P3) nanoparticles with tunable physical properties and crystal structures for potential applications in IR technologies. Low-cost, less-non-toxic, and abundantly-produced Ge1-xSnx alloys are an interesting class of narrow energy-gap semiconductors that received noteworthy interest in optical technologies. Admixing of α-Sn into Ge results in an indirect-to-direct bandgap crossover significantly improving light absorption and emission relative to indirect-gap Ge. However, the narrow energy-gaps reported for bulk Ge1-xSnx alloys have become a major impediment for their widespread application in optoelectronics. Herein, we report the first colloidal synthesis of Ge1-xSnx alloy quantum dots (QDs) with narrow size dispersity (3.3±0.5 – 5.9±0.8 nm), wide range of Sn compositions (0–20.6%), and composition-tunable energy-gaps and near infrared (IR) photoluminescence (PL). The structural analysis of alloy QDs indicates linear expansion of cubic Ge lattice with increasing Sn, suggesting the formation of strain-free nanoalloys. The successful incorporation of α-Sn into crystalline Ge has been confirmed by electron microscopy, which suggests the homogeneous solid solution behavior of QDs. The quantum confinement effects have resulted in energy gaps that are significantly blue-shifted from bulk Ge for Ge1-xSnx alloy QDs with composition-tunable absorption onsets (1.72–0.84 eV for x=1.5–20.6%) and PL peaks (1.62–1.31 eV for x=1.5–5.6%). Time-resolved PL (TRPL) spectroscopy revealed microsecond and nanosecond timescale decays at 15 K and 295 K, respectively owing to radiative recombination of dark and bright excitons as well as the interplay of surface traps and core electronic states. Realization of low-to-non-toxic and silicon-compatible Ge1-xSnx QDs with composition-tunable near IR PL allows the unprecedented expansion of direct-gap Group IV semiconductors to a wide range of biomedical and advanced technological studies. Tin phosphides are a class of materials that received noteworthy interest in photocatalysis, charge storage and thermoelectric devices. Dual stable oxidation states of tin (Sn2+ and Sn4+) enable tin phosphides to exhibit different stoichiometries and crystal phases. However, the synthesis of such nanostructures with control over morphology and crystal structure has proven a challenging task. Herein, we report the first colloidal synthesis of size, shape, and phase controlled, narrowly disperse rhombohedral Sn4P3, hexagonal SnP, and amorphous tin phosphide nanoparticles (NPs) displaying tunable morphologies and size dependent physical properties. The control over NP morphology and crystal phase was achieved by tuning the nucleation/growth temperature, molar ratio of Sn/P, and incorporation of additional coordinating solvents (alkylphosphines). The absorption spectra of smaller NPs exhibit size-dependent blue shifts in energy gaps (0.88–1.38 eV) compared to the theoretical value of bulk Sn3P4 (0.83 eV), consistent with quantum confinement effects. The amorphous NPs adopt rhombohedral Sn4P3 and hexagonal SnP crystal structures at 180 and 250 °C, respectively. Structural and surface analysis indicates consistent bond energies for phosphorus across different crystal phases, whereas the rhombohedral Sn4P3 NPs demonstrate Sn oxidation states distinctive from those of the hexagonal and amorphous NPs owing to complex chemical structure. All phases exhibit N(1s) and ʋ(N-H) energies suggestive of alkylamine surface functionalization and are devoid of tetragonal Sn impurities.

Li- and Na- Ion Batterry Anode Materials

Bio-Imaging and Sensing

Inorganic Chemistry

Materials Chemistry