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SYNTHESIS AND CHARACTERIZATION OF HYBRID ELECTROLYTES WITH TETHERED IONIC LIQUID FOR LITHIUM ION BATTERIES.

SYNTHESIS AND CHARACTERIZATION OF HYBRID ELECTROLYTES WITH TETHERED IONIC LIQUID FOR LITHIUM ION BATTERIES.
Author: Guang Yang
Publisher:
Total Pages:
Release: 2018
Genre:
ISBN:
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Rechargeable lithium ion batteries are revolutionary energy storage systems widely used in portable electronic devices (e.g., mobile phones, laptops) and more recently electrical vehicles. The conventional liquid electrolytes in the lithium ion battery brought about safety problems such as fire and explosion. Related safety accidents (e.g., cell phone explosion, laptop fire, plane smoldering, etc.) have been reported many times. This also eliminates the possibility of using lithium metal as anode material which has much higher theoretical specific capacity in comparison with commercial graphite electrode because of the growth of uncontrolled lithium dendrites can lead to short circuit and other serious accidents. Solid polymer electrolytes have many advantages over conventional liquid electrolytes. They are light-weighted, non-volatile and have much better safety features than liquid electrolyte. Meanwhile, they are also better than the ceramic electrolyte in terms of their excellent flexibility and processability. Currently, low ionic conductivity of solid polymer electrolytes (e.g., polyethylene oxide (PEO)) at ambient temperature still hinders their practical application. Ionic liquids (ILs) are non-flammable and have negligible volatility. Its ionic conductive nature, excellent chemical stability, and good electrochemical stability enable them to be regarded as useful components for next generation battery electrolytes. In this thesis work, focus will be placed on synthesis and characterization of ionic liquid tethered organic/inorganic hybrid polymer electrolyte with high room temperature ionic conductivity. Moreover, their electrochemical properties and prototype battery performances were also looked into. The use of highly conductive solid-state electrolytes to replace conventional liquid organic electrolytes enables radical improvements in reliability, safety and performance of lithium batteries. Here in chapter 2, we report the synthesis and characterization of a new class of nonflammable solid electrolytes based on the grafting of ionic liquids onto octa-silsesquioxane. The electrolyte exhibits outstanding room-temperature ionic conductivity (~4.8 10-4 S/cm), excellent electrochemical stability (up to 5 V relative to Li+/Li) and high thermal stability. All-solid-state Li metal batteries using the prepared electrolyte membrane are successfully cycled with high coulombic efficiencies at ambient temperature. Good cycling stability of the electrolyte against lithium has been demonstrated. This work provides a new platform of solid polymer electrolyte for the application of room-temperature lithium batteries. In chapter 3, an organic-inorganic hybrid solid electrolyte with ionic liquid moieties tethered onto dumbbell-shaped octasilsesquioxanes through oligo(ethylene glycol) spacers was synthesized. The hybrid electrolyte is featured by its high room-temperature ionic conductivity (1.210-4 S/cm at 20 oC with LiTFSI salt), excellent electrochemical stability (4.6 V vs Li+/Li), and great thermal stability. Excellent capability of the hybrid electrolyte to mediate electrochemical deposition and dissolution of lithium has been demonstrated in the symmetrical lithium cells. No short circuit has been observed after more than 500 hrs in the polarization tests. Decent charge/discharge performance has been obtained in the prepared electrolyte based all-solid-state lithium battery cells at ambient temperature. In chapter 4, hybrid polymer electrolyte network (XPOSS-IL) synthesized by crosslinking the individual dendritic POSS-IL was investigated. To be specific, after grafting mono-broninated hexaethylene glycol to the POSS cage, 1-vinyl imidazole was adopted for the subsequent quarternization reaction. Then the chain end double bonds underwent free radical crosslinking process to produce XPOSS-IL. The ionic conductivity of LiTFSI dissolved XPOSS-IL is 5.4 10-5 S/cm at 30 . By adding a small fraction of ionic liquid 1-ethyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide (EMITFSI), the ionic conductivity increases to 1.4 10-4 S/cm at room temperature. It is also found that EMITFSI will enhance the anodic stability of XPOSS-IL. The Li/LTO and Li/LFP cell assembled with X-POSS-IL-LiTFSI/EMITFSI demonstrates capability of delivering high specific capacities at room temperature and elevated temperature.

Polymer Electrolytes

Polymer Electrolytes
Author: Tan Winie
Publisher: John Wiley & Sons
Total Pages: 416
Release: 2020-02-18
Genre: Science
ISBN: 3527342001
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A comprehensive overview of the main characterization techniques of polymer electrolytes and their applications in electrochemical devices Polymer Electrolytes is a comprehensive and up-to-date guide to the characterization and applications of polymer electrolytes. The authors ? noted experts on the topic ? discuss the various characterization methods, including impedance spectroscopy and thermal characterization. The authors also provide information on the myriad applications of polymer electrolytes in electrochemical devices, lithium ion batteries, supercapacitors, solar cells and electrochromic windows. Over the past three decades, researchers have been developing new polymer electrolytes and assessed their application potential in electrochemical and electrical power generation, storage, and conversion systems. As a result, many new polymer electrolytes have been found, characterized, and applied in electrochemical and electrical devices. This important book: -Reviews polymer electrolytes, a key component in electrochemical power sources, and thus benefits scientists in both academia and industry -Provides an interdisciplinary resource spanning electrochemistry, physical chemistry, and energy applications -Contains detailed and comprehensive information on characterization and applications of polymer electrolytes Written for materials scientists, physical chemists, solid state chemists, electrochemists, and chemists in industry professions, Polymer Electrolytes is an essential resource that explores the key characterization techniques of polymer electrolytes and reveals how they are applied in electrochemical devices.

The Synthesis and Characterization of Ionic Liquids for Alkali-metal Batteries and a Novel Electrolyte for Non-humidified Fuel Cells

The Synthesis and Characterization of Ionic Liquids for Alkali-metal Batteries and a Novel Electrolyte for Non-humidified Fuel Cells
Author: Telpriore G. Tucker
Publisher:
Total Pages: 279
Release: 2014
Genre: Electrochemistry
ISBN:
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This thesis focused on physicochemical and electrochemical projects directed towards two electrolyte types: 1) class of ionic liquids serving as electrolytes in the catholyte for alkali-metal ion conduction in batteries and 2) gel membrane for proton conduction in fuel cells; where overall aims were encouraged by the U.S. Department of Energy. Large-scale, sodium-ion batteries are seen as global solutions to providing undisrupted electricity from sustainable, but power-fluctuating, energy production in the near future. Foreseen ideal advantages are lower cost without sacrifice of desired high-energy densities relative to present lithium-ion and lead-acid battery systems. Na/NiCl2 (ZEBRA) and Na/S battery chemistries, suffer from high operation temperature (>300C) and safety concerns following major fires consequent of fuel mixing after cell-separator rupturing. Initial interest was utilizing low-melting organic ionic liquid, [EMI+][AlCl4-], with well-known molten salt, NaAlCl4, to create a low-to-moderate operating temperature version of ZEBRA batteries; which have been subject of prior sodium battery research spanning decades. Isothermal conductivities of these electrolytes revealed a fundamental kinetic problem arisen from "alkali cation-trapping effect" yet relived by heat-ramping>140C. Battery testing based on [EMI+][FeCl4-] with NaAlCl4 functioned exceptional (range 150-180C) at an impressive energy efficiency>96%. Newly prepared inorganic ionic liquid, [PBr4+][Al2Br7-]:NaAl2Br7, melted at 94C. NaAl2Br7 exhibited super-ionic conductivity 10-1.75 Scm-1 at 62C ensued by solid-state rotator phase transition. Also improved thermal stability when tested to 265C and less expensive chemical synthesis. [PBr4+][Al2Br7-] demonstrated remarkable, ionic decoupling in the liquid-state due to incomplete bromide-ion transfer depicted in NMR measurements. Fuel cells are electrochemical devices generating electrical energy reacting hydrogen/oxygen gases producing water vapor. Principle advantage is high-energy efficiency of up to 70% in contrast to an internal combustion engine

Ionic Liquid-tethered Hybrid Nanoparticle Electrolytes for Secondary Lithium Batteries

Ionic Liquid-tethered Hybrid Nanoparticle Electrolytes for Secondary Lithium Batteries
Author: Yingying Lu
Publisher:
Total Pages: 452
Release: 2014
Genre:
ISBN:
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Rechargeable lithium-based battery is one of the most promising battery candidates for high energy storage devices. Batteries containing lithium metal, eschewed the use of carbon supporting materials can lead to as much as a ten-fold improvement in anode storage capacity from 360 mAh g-1 to 3860 mAh g-1 and would open up opportunities for high energy un-lithiated cathode materials such as sulfur and oxygen, among others. Unfortunately, significant improvements in safe and stable battery performance are needed due to the non-uniform lithium deposition on the negative electrode. These uneven dendritic structures increase the potential risk of cell short-circuiting, energy fading or even fire hazards. Recent discoveries and advances have focused on electrolyte reconfigurations for the sake of suppressing or even eliminating dendrite formation. Of the various options, ionic liquids offer multiple synergetic properties that make them attractive electrolytes for extending lifetime and safety of LMBs. Their inherently low vapor pressure, non-flammability, good electrochemical stability in the presence of metallic lithium make ILs excellent choice in fail-safe LMBs. When anchored to metal oxide nanoparticle surface, it promotes the mechanical strength as well as maintaining the advantages of ILs. This dissertation researches ionic liquid-tethered hybrid nanoparticle electrolytes with several goals: improving room temperature ionic conductivity of the electrolytes while maintaining chemical and mechanical stabilities, improving lithium-ion transference number, and studying the dendritic lithium metal growth as a function of electrolyte properties. It is found that all types of IL electrolytes show improvements over the conventional electrolytes such as propylene carbonate in LiTFSI. It also found that untethered IL has comparable cell lifetime to tethered IL and piperidinium-based IL suppresses dendrite growth more efficiently than imidazolium-based IL. Later in this dissertation, we discussed the efforts of extending the cell lifetime beyond ionic 3 liquid platform. Chapter 7 and 8 evaluate the battery performance and cell lifetime by adding fluorine generating salt and by employing single ion conductor, respectively. 4.

Ceramic and Specialty Electrolytes for Energy Storage Devices

Ceramic and Specialty Electrolytes for Energy Storage Devices
Author: Prasanth Raghavan
Publisher: CRC Press
Total Pages: 335
Release: 2021-04-04
Genre: Technology & Engineering
ISBN: 1000351807
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Ceramic and Specialty Electrolytes for Energy Storage Devices, Volume II, investigates recent progress and challenges in a wide range of ceramic solid and quasi-solid electrolytes and specialty electrolytes for energy storage devices. The influence of these electrolyte properties on the performance of different energy storage devices is discussed in detail. Features: • Offers a detailed outlook on the performance requirements and ion transportation mechanism in solid polymer electrolytes • Covers solid-state electrolytes based on oxides (perovskite, anti-perovskite) and sulfide-type ion conductor electrolytes for lithium-ion batteries followed by solid-state electrolytes based on NASICON and garnet-type ionic conductors • Discusses electrolytes employed for high-temperature lithium-ion batteries, low-temperature lithium-ion batteries, and magnesium-ion batteries • Describes sodium-ion batteries, transparent electrolytes for energy storage devices, non-platinum-based cathode electrocatalyst for direct methanol fuel cells, non-platinum-based anode electrocatalyst for direct methanol fuel cells, and ionic liquid-based electrolytes for supercapacitor applications • Suitable for readers with experience in batteries as well as newcomers to the field This book will be invaluable to researchers and engineers working on the development of next-generation energy storage devices, including materials and chemical engineers, as well as those involved in related disciplines.

Electrolytes for Lithium and Lithium-Ion Batteries

Electrolytes for Lithium and Lithium-Ion Batteries
Author: T. Richard Jow
Publisher: Springer
Total Pages: 488
Release: 2014-05-06
Genre: Technology & Engineering
ISBN: 1493903020
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Electrolytes for Lithium and Lithium-ion Batteries provides a comprehensive overview of the scientific understanding and technological development of electrolyte materials in the last several years. This book covers key electrolytes such as LiPF6 salt in mixed-carbonate solvents with additives for the state-of-the-art Li-ion batteries as well as new electrolyte materials developed recently that lay the foundation for future advances. This book also reviews the characterization of electrolyte materials for their transport properties, structures, phase relationships, stabilities, and impurities. The book discusses in-depth the electrode-electrolyte interactions and interphasial chemistries that are key for the successful use of the electrolyte in practical devices. The Quantum Mechanical and Molecular Dynamical calculations that has proved to be so powerful in understanding and predicating behavior and properties of materials is also reviewed in this book. Electrolytes for Lithium and Lithium-ion Batteries is ideal for electrochemists, engineers, researchers interested in energy science and technology, material scientists, and physicists working on energy.