Spelling suggestions: "subject:"solid state batteries"" "subject:"polid state batteries""
11 |
Quantum mechanical modelling and electrochemical stability of sodium based glassy electrolyte for all-solid-state batteriesFalk, Carolina, Johansson, Linnéa January 2022 (has links)
Increasing energy demand draws attention to new materials for improving current energy storage technologies. Particular interest is directed at solid state batteries and glass Na3ClO electrolyte is a promising candidate. In this report we explore some of the properties of this new glass and its capabilities as a potential electrolyte for a solid-state battery. The two aims of the study were to model the amorphous structure of the glass using the stochastic quenching method based on density functional theory as well as assessing the electrochemical stability of it against a metallic sodium electrode. Using VASP, a computational code based on density functional theory, we performed calculations of two 150 atom supercells, where the atoms were moved around until the systems were relaxed to obtain two glass models and the resulting structures were analyzed and characterized. The characterization of the structures was made by means of partial radial distribution functions, angle distribution functions, coordination numbers and bond lengths, which showed that the two models are statistically equivalent and either one can be used for the stability assessment of the glass. The electrochemical stability was assessed by inserting an extra sodium atom in possible holes in the glass model and calculating the energetics of Na insertion in each of these holes. This was made for 30 different hole positions. The reduction potential indicates the stability of each hole and the results was plotted as an energy distribution. Two peaks in the energy distribution, located at positive and negative energies, indicating stable and unstable holes, respectively. This indicates that the amorphous structure of the glass allows Na ions to travel (unstable holes). The stable peak has a greater probability density, which indicates a stable electrolyte against sodium metal electrode, though a larger sampling of holes is required for better statistics. / Ökande krav på energiefterfrågan uppmärksammar nya material för att förbättra nuvarande energilagringsteknik, med fokus på solida batterier och glaset Na3ClO som en lovande kandidat för elektrolyt. I denna rapport undersöks några av egenskaperna för glaset samt möjligheten för denna att fungera som elektrolyt i ett solid-state batteri. Målen med projektet var att modellera den amorfa strukturen av glaset genom att använda stochastic quenching method som baseras på density functional theory samt undersöka den elektrokemiska stabiliteten mot en metallisk natrium elektrod. Genom användning av VASP, beräkningskoder baserade på density functional theroy, beräknades två superceller med 150 atomer vardera där atomerna flyttas runt tills dess att systemet var relaxerat och två modeller av glaset erhölls. Dessa var sedan visualiserades och karakteriserade. Karakterisering av strukturerna gjordes genom en partiella radiella fördelningsfunktioner, vinkel distrubitionsfunktioner, koordinationsnummer och bindningslängder. Detta visade på statistisk ekvivalens, vilket innebär att båda modellerna kan användas för vidare stabilitetsundersökning. Den elektrokemiska stabiliteten undersöktes genom att sätta in en extra natrium atom i möjliga hål i glas modellen samt beräkna dess energier av Na insättning i respektive hål. Detta gjordes för 30 olika positioner för hålen. Reduktionspotentialen indikerar stabiliteten för respektive hål, och resultatet plottades som en energidistribution. Två toppar i energidistributionen, lokaliserade vid positiva och negativa energier, indikerar stabila respeltive instabila hål. Detta indikerar på att den amorfa strukturen för glaset tillåter Na joner att färdas (instabila hål). Den stabila toppen har en större sannolikhetstäthet vilket indikerar på en stabil elektrolyt mot en metallisk natrium elektrod, men en större samling hål krävs för en bättre statistisk säkerhet.
|
12 |
Design, Development and Structure of Liquid and Solid Electrolytes for Lithium BatteriesAl-Salih, Hilal 11 September 2023 (has links)
Energy storage is crucial for intermittent renewable energy sources, electric vehicles, and portable devices. The continuously increasing energy consumption in these industries necessitates the enhancement of commercial lithium-ion batteries (LIB), especially regarding their safety and energy density. Historically, aqueous electrolytes were the norm in the battery industry. Prior to the development of lithium batteries, most commercially significant batteries used water as the solvent. In the past decade, "highly concentrated" electrolytes resurrected the notion of an aqueous lithium-ion battery (ALIB). Significant efforts have been made since then to comprehend the interfacial stability of these high-concentration electrolytes, and make them suitable for use in batteries especially high voltage ones. Another candidate for future batteries is All-Solid-State Batteries (ASSB) as they have the potential to double, or even triple, the energy density figures we currently achieve in LIBs mainly due to their ability to utilize lithium metal anode which has the highest specific capacity among anodes (3860 mAh g⁻¹), lowest reduction potential (-3.04 V vs SHE), and low density (0.53 g cm⁻³).
This thesis first proposes a phenomenological model to describe the microstructure of aqueous electrolyte and the relation between their phase diagrams with ionic conductivity; highlighting a common correlation between the eutectic composition and peak ionic conductivity in conductivity isotherms. we then propose an empirical model correlating ionic conductivity with both molar concentration and temperature. The aim of this portion of the thesis is to provide an in depth understanding of aqueous electrolytes' physical properties in a way that can help researchers optimize the energy density and the cost of ALIBs.
Moving further, the thesis presents two novel composite solid electrolytes (CSE) that were developed and fully characterized. Both of which were composed of the following four components; polyethylene oxide (PEO), lithium bis(trifluoromethanesulfonyl)imide (LiTFSI) salt, lithium lanthanum titanate (LLTO) perovskite inorganic ceramic and the polymer plasticizer succinonitrile (SN). The careful formulation of these CSEs was based on the trade-off between film forming ability and ionic conductivity. The optimized polymer rich CSE proved to have better characteristics when compared to its ceramic rich alternative. ASSBs employing both CSEs were successfully charged and discharged when coupled with lithium metal anode and in-lab prepared composite cathode. The developed thin and flexible CSEs could be utilized in small applications (Wh-KWh) such as in consumer electronics and flexible biomedical devices (e.g., pacemakers) or larger applications (kWh-MWh) such as in EVs and large format storage for the electrical grid.
|
13 |
Surface Functionalization of LiNi₇.₀Co₀.₁₅Mn₀.₁₅O₂ with Fumed Li₂ZrO₃ via a Cost-Effective Dry-Coating Process for Enhanced Performance in Solid-State BatteriesCangaz, Sahin, Hippauf, Felix, Takata, Ryo, Schmidt, Franz, Dörfler, Susanne, Kaskel, Stefan 05 March 2024 (has links)
Applying a thin film coating is a vital strategy to enhance long term and interface stability of Ni-rich layered oxide cathode materials (NRLOs), especially when they are matched with sulfidic solid electrolytes (SSEs) in solid-state batteries (SSBs). The coating prevents direct contact between the cathode active material (CAM) and the SSE, shielding against parasitic side reactions at the cathode electrolyte interface (CEI). Conventional coatings are based on wet-chemical methods and therefore harmful to the environment and require long-lasting processing and high costs. In this study, we present a versatile, facile and highly-scalable dry-coating method (with suitable equipment up to 500 kg per batch) successfully employed for both multiand single-crystalline LiNi₇.₀Co₀.₁₅Mn₀.₁₅O₂ (NCM70) particles by fumed Li₂ZrO₃ nanostructured particles (LZONPs) via high intensity mixing process. The resulting porous coating layer stays firmly attached at the CAM particle surface without a need of post-calcination step at elevated temperatures. The electrochemical testing results signify enhanced rate capability up to 1.5 mAcm⁻² for both particle types and cyclic stability up to 650 cycles with a capacity retention of 86.1% for singlecrystalline NCM70. We attribute the enhanced performance to the reduced CEI reactions as cathodic charge transfer resistance depressed significantly after dry-coating by LZONPs, being an important step towards sulfidic solid-state batteries.
|
14 |
Paper-based lithium-Ion batteries using carbon nanotube-coated wood microfiber current collectorsAliahmad, Nojan 06 November 2013 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / The prevalent applications of energy storage devices have incited wide-spread efforts on production of thin, flexible, and light-weight lithium-ion batteries. In this work, lithium-ion batteries using novel flexible paper-based current collectors have been developed. The paper-based current collectors were fabricated from carbon nanotube (CNT)-coated wood microfibers (CNT-microfiber paper). This thesis presents the fabrication of the CNT-microfiber paper using wood microfibers, coating electrode materials, design and assemblies of battery, testing methodologies, and experimental results and analyses.
Wood microfibers were coated with carbon nanotubes and poly(3,4-ethylenedioxythiophene) (PEDOT) through an electrostatic layer-by-layer nanoassembely process and formed into a sheet, CNT-microfiber paper. The CNT loading of the fabricated paper was measured 10.1 μg/cm2 subsequently considered.
Electrode material solutions were spray-coated on the CNT-microfiber paper to produce electrodes for the half and full-cell devices. The CNT current collector consists of a network structure of cellulose microfibers at the micro-scale, with micro-pores filled with the applied conductive electrode materials reducing the overall internal resistance for the cell. A bending test revealed that the paper-based electrodes, compared to metal ones, incurred fewer damages after 20 bends at an angle of 300o. The surface fractures on the paper-based electrodes were shallow and contained than metallic-based electrodes. The micro-pores in CNT-microfiber paper structure provides better adherence to the active material layer to the substrate and inhibits detachment while bending.
Half-cells and full-cells using lithium cobalt oxide (LCO), lithium titanium oxide (LTO), and lithium magnesium oxide (LMO) were fabricated and tested. Coin cell assembly and liquid electrolyte was used. The capacities of half-cells were measured 150 mAh/g with LCO, 158 mAh/g with LTO, and 130 mAh/g with LMO. The capacity of the LTO/LCO full-cell also was measured 126 mAh/g at C/5 rate. The columbic efficiency of the LTO/LCO full-cell was measured 84% for the first charging cycle that increased to 96% after second cycle. The self-discharge test of the full-cell after charging to 2.7 V at C/5 current rate is showed a stable 2 V after 90 hours.
The capacities of the developed batteries at lower currents are comparable to the metallic electrode-based devices, however, the capacities were observed to drop at higher currents. This makes the developed paper-based batteries more suitable for low current applications, such as, RFID tags, flexible electronics, bioassays, and displays. The capacities of the batteries at higher current can be improved by enhancing the conductivity of the fibers, which is identified as the future work. Furthermore, fabrication of an all solid state battery using solid electrolyte is also identified as the future work of this project.
|
15 |
Synthesis of lithium manganese phosphate by controlled sol-gel method and design of all solid state lithium ion batteriesPenumaka, Rani Vijaya January 2015 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Due to the drastic increase in the cost of fossil fuels and other environmental issues, the demand for energy and its storage has risen globally. Rather than being dependent on intermittent energy sources like wind and solar energy, focus has been on alternative energy sources. To eliminate the need for fossil fuels, advances are being made to provide energy for hybrid electric vehicles (HEV), plug-in hybrid vehicles (PHEV) and pure electric vehicles (EV) thus providing scope for much greener environment. Hence, focus has been on development in lithium ion batteries to provide with materials that have high energy density and voltage.
Ortho olivine lithium transitional metals are known to be abundant and inexpensive; these compounds are less noxious than other cathode materials. Advancement in research is being done in finding iron and manganese compounds as cathode materials for advanced technologies. However, Lithium manganese phosphates are known to suffer with poor electrochemical performances due the manganese dissolution in the organic liquid electrolyte due to Jahn-Teller Lattice distortion. This problem was tried to endorse in this thesis. In the second chapter by synthesizing nano sized cathode particles with good electronic conductivity, good performance was achieved.
In the third chapter additive olivine cathode was synthesized my modified sol gel process. A wt. % of TMSP was added as an additive in the organic liquid electrolyte. By comparing the properties between the two kinds of electrolytes it was observed that by the addition of the additive in the organic electrolyte good electrochemical properties could be achieved hindering the Mn dissolution in the electrolyte.
In the final chapter, a composite solid electrolyte was fabricated by using NASICON-type glass ceramic of Lithium aluminum titanium phosphate (LATP) with organic binder of Polyethylene oxide. The flexible solid electrolyte exhibited good ionic conductivity. An all solid state cell was fabricated using the composite solid electrolyte using LiMn2O4 as the symmetric electrodes. At different pressures, the performance of the solid state cell was studied.
|
16 |
Struktur-Eigenschafts-Beziehungen von Polymerelektrolyten basierend auf ionischen Flüssigkeiten für die Anwendung in FestkörperbatterienEhrlich, Lisa 19 September 2024 (has links)
Die globalen Herausforderungen unserer Zeit sind wesentlich geprägt vom Klimawandel und der Umweltzerstörung auf dem Planeten Erde, hervorgerufen durch die Existenz des Menschen. Damit sind die Themen der Nachhaltigkeit, des Umweltschutzes und der alternativen Energieerzeugung, verbunden mit der Energiespeicherung, allgegenwärtig. Auf dem Gebiet der mobilen Energiespeicher sind die Lithium-Ionen-Batterien (LIB) fest etabliert. Jedoch sind die Ressourcen für das Metall Lithium endlich und die großtechnische Anwendung dieser Systeme ist mit hohen Sicherheitsmaßnahmen und damit hohen Kosten verbunden. Deshalb wird zunehmend an Lithium-freien Batterien geforscht.
Diese Arbeit befasste sich mit der Entwicklung von Komponenten einer Lithium-freien, rein-organischen Festkörperbatterie. Die Herausforderungen an solche komplexen Systeme sind besonders hoch, sodass sich diese Arbeit auf die gezielte Entwicklung geeigneter Elektrolytmaterialien für organische Festkörperbatterien fokussierte. Die bisher genutzten Flüssigelektrolytsysteme in LIB bringen einige Nachteile mit sich (z.B. Feuchtigkeitsempfindlichkeit, Toxizität, leichte Entzündlichkeit), welche adressiert werden müssen. Kohlenstoffhaltige Polymere sind prinzipiell relativ leicht synthetisierbar und die Verfügbarkeit an Kohlenstoff, ist im Vergleich zu Lithium deutlich größer. Weiterhin sind Polymere flexibler als herkömmliche Batteriekomponenten, was die Anwendung für dünne elektronische Geräte attraktiv macht.
Basierend auf den Vorarbeiten der Arbeitsgruppe Pospiech, welche sich mit Bis(trifluormethansulfonyl)imid-haltigen ionisch-flüssigen Polymerelektrolyten für LIB beschäftigten, sollten in dieser Arbeit ebenfalls ionische Flüssigkeiten als Grundlage für Polymerelektrolyte für organische Redox-Batterien dienen. Der Neuheitsgrad dieser Arbeit liegt jedoch in der Verwendung von Chlorid-Ionen-haltigen, ionisch-flüssigen Polymerelektrolyten, welche als Chlorid-Ionen-Leiter in der organischen Batterie fungieren sollen. Aufgrund der festen Polymermatrix agieren diese dabei nicht nur als Festelektrolyte, sondern auch als Separatoren, weshalb eine gewisse mechanische Festigkeit mit einer ausreichenden Flexibilität kombiniert werden muss.
Zur Realisierung der Aufgabenstellung wurden zunächst neuartige Chlorid-Ionen-haltige Polymerelektrolyte, sowohl als lineare Homopolymere als auch als vernetzte Polymere, synthetisiert. Dabei war das Ziel, die Systeme im Hinblick auf die ionischen Leitfähigkeiten und damit verbunden den Ladungstransfer der Chlorid-Ionen zu optimieren. Dies sollte zum einen durch strukturelle Veränderungen (Wahl des Spacers und der Endgruppe) als auch durch die Verwendung von verschiedenen Vernetzer- und Leitsalzkonzentrationen realisiert werden. Im zweiten Schritt wurde die systematische Variation der Polymerstruktur genutzt, um Struktur-Eigenschafts-Beziehungen, insbesondere hinsichtlich der ionischen Leitfähigkeit auszuarbeiten. Im dritten Schritt fanden ausgewählte Systeme dann letztendlich Anwendung in Batteriezellen, um die Frage zu beantworten, ob die Anforderungen an den Festkörperelektrolyten tatsächlich erreicht werden können und es damit möglich ist, in solchen Systemen lösungsmittelfrei zu arbeiten, oder ob die Eigenschaften, wie z.B. die ionische Leitfähigkeit, nicht ausreichen und durch Zugabe geeigneter Zusätze ein Gelelektrolyt angewandt werden sollte.
Mit der dargestellten Vorgehensweise ist es im Rahmen dieser Doktorarbeit gelungen, neuartige Chlorid-Ionen-leitende Polymerelektrolyte für Batteriesysteme zu entwickeln, welche auf ionisch-flüssigen Monomeren basieren und somit ein deutlich geringeres Sicherheitsrisiko mit sich bringen, als es herkömmliche Flüssigelektrolytsysteme bisher tun. Das Gesamtziel dieser Arbeit wurde somit erfolgreich erreicht. Es wurden folgende wesentliche Ergebnisse erzielt:
(1) Durch systematische Variationen in der Monomerstruktur, verschiedene Polymerisationsmethoden und Additive konnte eine Vielzahl an neuartigen Chlorid-haltigen Polymerelektrolyten synthetisiert und chemisch sowie chemisch-physikalisch charakterisiert werden.
(2) Die Struktur-Eigenschafts-Beziehungen der Polymere wurden sehr detailliert herausgearbeitet. Dabei wurde insbesondere der Einfluss der C-Atom-Anzahl in der acrylischen Seitenkette, die Menge an Vernetzer und Leitsalz auf das thermische, mechanische, chemische und elektrochemische Verhalten der Proben untersucht und verstanden.
(3) Damit wurde das Basiswissen für eine effiziente Übertragung auf ein Batteriesystem erarbeitet.
(4) Erste Implementierungen der neuen Systeme als Elektrolyte in Poly(2,2,6,6-tetramethylpiperidinyloxyl-methacrylat)/ Zink-Batterien wurden erfolgreich durchgeführt und zeigten mit Leitfähigkeiten von 10-3 S·cm-1 vielversprechende Ergebnisse.
Eine solche Breite an strukturellen Variationen in Chlorid-Ionen-haltigen Polymeren, welche mit zahlreichen Methoden detailliert analysiert und anschließend in Batteriezellen als Gel- und Festelektrolyte getestet wurden, konnte bisher in der Literatur noch nicht gefunden werden und stellt einen erheblichen Neuheitsgrad dieser Arbeit und einen guten Ausgangspunkt zur Implementierung in Batterien dar.:Inhaltsverzeichnis
Danksagung i
Inhaltsverzeichnis iii
Abbildungsverzeichnis vii
Tabellenverzeichnis xiv
Abkürzungs- und Symbolverzeichnis xvi
1 Einleitung 1
2 Theoretischer Hintergrund 6
2.1 Die Lithium-Ionen-Batterie (LIB) 6
2.2 Struktur und Aufbau von polymerbasierten Batterien 8
2.2.1 Redox-Flow-Batterien (RFB) 8
2.2.2 Organische Festkörperbatterien (SSB) 11
2.3 Elektrolyttypen für (polymerbasierte) Batterien 19
2.3.1 Überblick 19
2.3.2 Flüssigelektrolyte 20
2.3.2.1 Lösungsmittel 20
2.3.2.2 Leitsalz 22
2.3.2.3 Elektrolyte basierend auf ionischen Flüssigkeiten 23
2.3.3 Polymerelektrolyte (PEL) 27
2.3.3.1 Überblick 27
2.3.3.2 Festelektrolyte (SPE) 28
2.3.3.3 Gelpolymerelektrolyte (GPE) 30
2.3.3.4 Elektrolyte aus polyionischen Flüssigkeiten (PIL) 30
2.4 Synthese polymerer ionischer Flüssigkeiten 37
2.4.1 Freie radikalische Polymerisation (FRP) von IL-Monomeren 38
2.4.2 Reaktionsverfolgung 42
3 Zielstellung und Aufbau der Arbeit 44
4 Experimenteller Teil 47
4.1 Verwendete Chemikalien 47
4.2 Synthesen 49
4.2.1 Monomersynthesen 49
4.2.2 Polymersynthesen 56
4.2.2.1 Lineare Homopolymere (LHP) 56
4.2.2.2 PIL-Netzwerke 59
4.3 Angewandte Methoden, Verfahren und Geräte 60
4.3.1 Raman-Spektroskopie als Methode zur Reaktionsverfolgung 60
4.3.2 Charakterisierung der linearen Homopolymere 61
4.3.2.1 Kernspinresonanzspektroskopie (NMR-Spektroskopie) 61
4.3.2.2 Thermische Feld-Fluss-Fraktionierung (ThFFF) 61
4.3.2.3 Matrix-unterstützte Laser-Desorption/Ionisation gekoppelt mit Flugzeit-Massenspektrometrie (MALDI-TOF MS) 63
4.3.3 Methoden zur thermischen und mechanischen Stabilität bzw. Eigenschaften 64
4.3.3.1 Thermogravimetrische Analyse (TGA) 64
4.3.3.2 Dynamische Differenzkalorimetrie (DSC) 64
4.3.3.3 Rheologie 64
4.3.3.4 Quelluntersuchungen 66
4.3.4 Methoden zur Bestimmung elektrochemischer Eigenschaften 67
4.3.4.1 Elektrochemische Impedanz-Spektroskopie (EIS) 67
4.3.4.2 Linear-Sweep-Voltammetrie (LSV) 71
4.3.4.3 Cyclovoltammetrie (CV) 72
4.3.4.4 Raster-Kelvin-Mikroskopie (KPFM) 75
4.3.5 Methoden zur Untersuchung der morphologischen Struktur bzw. Eigenschaften 76
4.3.5.1 Rasterelektronenmikroskopie (REM) 76
4.3.5.2 Kleinwinkelröntgenstreuung (SAXS) 76
4.4 Batterietests 77
4.4.1 Zellaufbau 77
4.4.2 Parameter und Materialien für Zyklisierungstests 77
5 Ergebnisse und Diskussion 78
5.1 Darstellung des Forschungskonzeptes 78
5.2 Synthese und Polymerisation der IL-Monomere 80
5.2.1 Monomersynthesen 80
5.2.2 Polymersynthesen 82
5.2.2.1 Lineare Homopolymere 82
5.2.2.2 PIL-Netzwerke 83
5.3 Quellverhalten der PIL-Netzwerke 86
5.4 Charakterisierung der linearen Homopolymere und der PIL-Netzwerke 91
5.4.1 Bestimmung der molaren Massen der linearen Homopolymere 91
5.4.1.1 Thermische Feld-Fluss-Fraktionierung 91
5.4.1.2 Matrix-unterstützte Laser-Desorption/Ionisation gekoppelt mit Flugzeit-Massenspektrometrie 94
5.4.2 Thermisches Verhalten 95
5.4.2.1 TGA-Untersuchungen der linearen Homopolymere 95
5.4.2.2 TGA-Untersuchungen der PIL-Netzwerke 97
5.4.2.3 DSC-Untersuchungen der linearen Homopolymere 98
5.4.2.4 DSC-Untersuchungen der PIL-Netzwerke 101
5.4.3 Dynamisch-mechanisches Verhalten der PIL-Netzwerke 105
5.4.3.1 Komplexe Viskosität als Funktion der Temperatur 105
5.4.3.2 Bestimmung der Maschenweite und Vernetzungsdichte der PIL-Netzwerke 110
5.4.4 Ionische Leitfähigkeit und elektrochemisches Verhalten 113
5.4.4.1 EIS-Messungen der linearen Homopolymere 113
5.4.4.2 EIS-Messungen der PIL- Netzwerke 115
5.4.4.3 Linear-Sweep Voltammetrie der linearen Homopolymere und PIL-Netzwerke und Cyclovoltammetrie der linearen Homopolymere 123
5.4.5 Untersuchungen zum Ladungsträgertransport 125
5.4.5.1 Chlorid-Ionen-Diffusion 125
5.4.5.2 Raster-Kelvin-Mikroskopie 127
5.4.6 Strukturaufklärung mittels Kleinwinkelröntgenstreuung 131
5.5 Integration ausgewählter Systeme als Polymerelektrolyte in Batteriezellen 138
5.5.1 Wahl geeigneter Elektroden- und Elektrolytkombinationen 138
5.5.2 Zyklisierungstests 141
6 Zusammenfassung und Ausblick 146
7 Literaturverzeichnis 154
8 Anhang A
9 Publikationsliste L
10 Selbstständigkeitserklärung M
|
17 |
Etude des phases Li10MP2S12 (M=Sn, Si) comme électrolyte pour batteries tout-solide massives / Study of Li10MP2S12 (M=Sn, Si) phases as electrolyte for solid state batteriesTarhouchi, Ilyas 07 December 2015 (has links)
En remplaçant l’électrolyte liquide par un solide, les batteries tout-solide massivessont souvent considérées comme une solution aux problèmes de sécurité desbatteries Li-ion actuelles. La récente découverte du matériau Li10GeP2S12 destructure dite LGPS présentant une conductivité ionique équivalente à celles desélectrolytes liquides a réactivé ce domaine de recherche.Dans cette optique, nous avons étudié les matériaux Li10MP2S12 (M=Sn, Si) destructure LGPS, au moyen de diverses caractérisations structurales (DRX,RMN du 31P, spectroscopie Mössbauer …), de propriétés de mobilité/conductionionique (RMN du 7Li, spectroscopie d’impédance) et de propriétés électrochimiques(voltammétrie cyclique, cyclage galvanostatique).Les échantillons commerciaux de Li10SnP2S12 contiennent des impuretés et uneincertitude subsiste sur la composition de la phase de structure LGPS. Lamodélisation des déplacements de RMN du 31P a notamment permis de mettre enévidence l’influence des lithium en site octaédrique adjacents. Les mesuresd’impédance suggèrent une réactivité avec le Li métallique et la voltammétrieconfirme que cette phase est très instable à bas potentiel, excluant son utilisation entant que simple électrolyte dans une batterie tout-solide. Nous proposons qu’il puisseêtre utilisé à la fois comme électrolyte et comme matériau de négative.L’étude préliminaire des matériaux au silicium souligne la difficulté d’obtention dematériau pur de structure LGPS, et conduit à la mise en cause du modèle structuraldit thio-LiSICON. Par ailleurs, elle montre là encore l’instabilité de ces matériauxface au lithium métal. / By replacing the liquid electrolyte by a solid one, solid state batteries are oftenconsidered as a solution to safety issues in current Li-ion batteries. The recentdiscovery of Li10GeP2S12 with so-called LGPS structure, which exhibits an ionicconductivity equivalent to that of liquid electrolytes, has boosted related researchactivities.In this perspective, we studied the Li10MP2S12 (M=Sn, Si) materials with LGPSstructure, using various methods to characterize the structure (XRD, 31P NMR,Mössbauer spectroscopy …), the ionic mobility/conductivity (7Li NMR, Impedancespectroscopy), and the electrochemical properties (cycling voltammetry,galvanostatic cycling) of the material.Commercially available Li10SnP2S12 batches contain impurities and there remains anambiguity in the actual composition of the LGPS type phase. Modelling of the 31PNMR shifts reveals the effect of lithium in neighboring octahedral sites. Impedencemeasurements suggest reactivity with Li metal, and cyclic voltammetry confirms thatthe material is highly unstable at low potential, which excludes its use as a simpleelectrolyte in solid state batteries. We propose that it might be used both as anelectrolyte and as a negative electrode.The preliminary study on silicon based materials highlights difficulties in obtaining apure LGPS-type compound and questions the real nature of the so-calledthio-LiSICON structural model. Besides, it also shows the instability of thesematerials versus lithium metal.
|
18 |
Sputter Deposited Thin Film Cathodes from Powder Target for Micro Battery ApplicationsRao, K Yellareswara January 2015 (has links) (PDF)
All solid state Li-ion batteries (thin film micro batteries) have become inevitable for miniaturized devices and sensors as power sources. Fabrication of electrode materials for batteries in thin film form has been carried out with the existing technologies used in semiconductor industry. In the present thesis, radio frequency (RF) sputtering has been chosen for deposition of cathode material (ceramic oxides) thin films because of several advantages such as precise thickness control and deposition of compound thin films with equivalent composition. Conventional sputtering involves fabrication of thin film using custom made pellet according to the specification of sputter gun. However several issues such as target breaking are inevitable with the pellet sputtering. To forfend the issues, powder sputtering has been implemented for the deposition of various thin film cathodes in an economically feasible approach. Optimization of various process parameters during film deposition of cathode materials LiCoO2, Li2MnO3, LiNixMnyO4, mixed oxide cathodes of LiMn2O4, LiCoO2 and TiO2 etc., have been executed successfully by the present approach to achieve optimum electrochemical performance. Thereafter the optimized process parameters would be useful for selection of cathode layers for micro battery fabrication.
Chapter 1 gives a brief introduction to the Li ion and thin film solid state batteries. It also highlights the advantages of powder sputtering compared to conventional pellet sputtering.
In Chapter 2, the materials used and methods employed for the fabrication of thin film electrodes and analytical characterizations have been discussed.
In chapter 3, implementation of powder sputtering for the deposition of LiCoO2 thin films has been discussed. X-Ray diffraction (XRD), X-Ray photoelectron spectroscopy (XPS) and electrochemical investigations have been carried out and promising results have been achieved. Charge discharge studies delivered a discharge capacity of 64 µAh µm-1 cm-2 in the first cycle in the potential range
3.0-4.2 V vs. Li/Li+. The possible causes for the moderate cycle life performance have been discussed.
Systematic investigations for RF power optimization for the deposition of Li2-xMnO3-y thin films have been carried out. Galvanostatic charge discharge studies delivered a highest discharge capacity of 139 µAh µm-1cm-2 in the potential window 2.0-3.5 V. Thereafter, effect of LMO film thickness on electrochemical performance has been studied in the thickness range 70 nm to 300 nm. Films of lower thickness delivered higher discharge capacity with good cycle life than the thicker films. These details are discussed in chapter 4.
In Chapter 5, fabrication and electrochemical performance of LiNixMnyO4 thin films are presented. LMO thin films have been deposited on nickel coated stainless steel substrates. The as deposited films were annealed at 500 °C in ambient conditions. Nickel diffuses in to LMO film and results in LiNixMnyO4 (LMNO) film. These films were further characterized. Electrochemical studies were conducted up to higher potential 4.4 V resulted in discharge capacities of the order of 55 µAh µm-1cm-2.
In chapter 6, electrochemical investigations of mixed oxide thin films of LiCoO2 and LiMn2O4 have been carried out. Electrochemical investigations have been carried out in the potential window 2.0–4.3 V and a discharge capacity of 24 µAh µm-1cm-2 has been achieved. In continuation, TiO2 powder was added to the former composition and the deposited films were characterized for electrochemical performance. The potential window as well as the discharge capacity enhanced after TiO2 doping. Electrochemical characterization has been carried out in the potential window 1.4–4.5 V, and a discharge capacity of 135 µAh µm-1cm-2 has been achieved.
Finally chapter 7 gives overall conclusions and future directions to the continuation of the work.
|
19 |
Étude des propriétés électriques et structurales de verres de sulfures au lithium pour électrolytes de batteries tout-solide / Electrical and structural properties of Li-sulfide glasses as electrolytes for all-solid-state batteriesCozic, Solenn 15 September 2016 (has links)
Le marché du stockage de l'énergie est en perpétuelle expansion, tant pour les applications nomades que fixes. Afin de répondre aux exigences requises pour les diverses applications (appareils électroniques, véhicules hybrides et électriques, stockage des énergies renouvelables…), des batteries toujours plus performantes, compactes et légères doivent être développées. Pour cela, les batteries utilisant du lithium métallique en tant qu'anode sont les plus attractives en termes de densités d'énergies. Néanmoins, l'utilisation d'électrolytes liquides conventionnels, généralement des solvants organiques inflammables, dans de tels dispositifs soulève des problématiques de sécurité. Les travaux de recherche présentés dans ce manuscrit concernent l'étude de matériaux vitreux pouvant être utilisés en tant qu'électrolyte solide afin de permettre le développement de batteries tout-solide sûres et performantes. Des verres de sulfures au lithium, attractifs pour leurs propriétés de conduction ionique, sont étudiés et caractérisés. Les propriétés de conduction ionique dans les verres étant toujours mal comprises et sujettes à controverses, l'analyse structurale des verres présente ici un réel intérêt pour une meilleure compréhension des corrélations entre structure et propriétés. Un effort de recherche a donc été porté sur l'étude de l'ordre local dans les verres préparés via différentes techniques d'analyse structurale complémentaires. Enfin, les matériaux vitreux, sont de manière générale relativement faciles à mettre en forme. Les verres étudiés dans ce manuscrit peuvent alors également être utilisés en tant qu'électrolytes sous forme de couches minces dans les micro-batteries. Des premiers essais de dépôts par pulvérisation cathodique RF magnétron de couches minces conductrices ont donc été effectués et constituent la première brique à la fabrication de micro-batteries. / The energy storage market is in constant growth for both portable and stationary applications. To satisfy the requirements of various applications (electronic devices, hybrid-electric vehicles, renewable energy storage…), always more efficient, more compact and lightweight batteries have to be developed. Then, thanks to their high energy densities, batteries using Li metal anodes are the most promising to complete this challenge. However, the use of conventional liquid electrolytes raises safety issues, mainly related to the flammability of the organic liquid. In this thesis, glassy materials, exhibiting great interest towards developing solid electrolytes are considered and might enable the development of safe and efficient all-solid-state batteries. Here, Li-sulfide glasses, attractive for their ionic conduction properties, have been studied and characterized. The ionic conduction properties of glasses are still misunderstood and controversial, the structural investigation of glasses is of great interest in order to get a better understanding of structure-properties relationship. Then, the short and intermediate range order of prepared glasses have been investigated by the mean of various complementary structural analysis techniques. Finally, glassy materials are usually quite easy to shape. Thus, studied glasses in this thesis can also be used as thin-film electrolytes in microbatteries. First tests of sputtering of conducting thin-films have been performed by RF magnetron sputtering and constitute a first step in order to design microbatteries.
|
Page generated in 0.0746 seconds