Crystalline Polymer And Small Molecule Electrolytes

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Crystalline Polymer And Small Molecule Electrolytes

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Author : David Andrew Ainsworth
language : en
Publisher:
Release Date : 2010

Crystalline Polymer And Small Molecule Electrolytes written by David Andrew Ainsworth and has been published by this book supported file pdf, txt, epub, kindle and other format this book has been release on 2010 with Crystalline polymers categories.

Crystalline Polymer And Small Molecule Electrolytes

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Author : David Andrew Ainsworth
language : en
Publisher:
Release Date : 2010

Crystalline Polymer And Small Molecule Electrolytes written by David Andrew Ainsworth and has been published by this book supported file pdf, txt, epub, kindle and other format this book has been release on 2010 with Crystalline polymers categories.

Polymer Electrolytes

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Author : César Sequeira
language : en
Publisher: Elsevier
Release Date : 2010-08-30

Polymer Electrolytes written by César Sequeira and has been published by Elsevier this book supported file pdf, txt, epub, kindle and other format this book has been release on 2010-08-30 with Technology & Engineering categories.

Polymer electrolytes are electrolytic materials that are widely used in batteries, fuel cells and other applications such as supercapacitors, photoelectrochemical and electrochromic devices. Polymer electrolytes: Fundamentals and applications provides an important review of this class of ionic conductors, their properties and applications.Part one reviews the various types of polymer electrolyte compounds, with chapters on ceramic polymer electrolytes, natural polymer-based polymer electrolytes, composite polymer electrolytes, lithium-doped hybrid polymer electrolytes, hybrid inorganic-organic polymer electrolytes. There are also chapters on ways of characterising and modelling polymer electrolytes. Part two discusses applications such as solar cells, supercapacitors, electrochromic and electrochemical devices, fuel cells and batteries.With its distinguished editors and international team of contributors, Polymer electrolytes: Fundamentals and applications is a standard reference for all those researching and using polymer electrolytes in such areas as battery and fuel cell technology for automotive and other applications. Provides an important review of this class of ionic conductors, their properties and applications in practical devices Explores categories of polymer electrolytes and conductivity measurements Features a comprehensive analysis of current developments in polymer electrolytes and highlights a new type of polymer electrolyte

Liquid Crystalline Polymers

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Author : A. M. Donald
language : en
Publisher: Cambridge University Press
Release Date : 2006-05-11

Liquid Crystalline Polymers written by A. M. Donald and has been published by Cambridge University Press this book supported file pdf, txt, epub, kindle and other format this book has been release on 2006-05-11 with Science categories.

A 2006 edition explaining the underlying science and applications of liquid crystalline polymers.

Ion Conduction In Crystalline Polymer Electrolytes For Lithium Ion Batteries

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Author : Shankar Ram Chithur Viswanathan
language : en
Publisher:
Release Date : 2021

Ion Conduction In Crystalline Polymer Electrolytes For Lithium Ion Batteries written by Shankar Ram Chithur Viswanathan and has been published by this book supported file pdf, txt, epub, kindle and other format this book has been release on 2021 with categories.

Polyethylene oxide (PEO) based Solid Polymer Electrolytes (SPEs) are safe and efficient alternatives to liquid/gel-based electrolytes. In addition to improving safety and design flexibility, SPEs could allow the use of lithium metal anode which can theoretically improve energy density 10-folds than commercially used lithium graphite anode. However, SPEs suffer from low Li+ ion conductivity. In most SPEs, the conductivity is linked to PEO segmental motion. Attempts to increase polymer dynamics reduce the mechanical strength of SPEs. Thus, it is necessary to decouple conductivity from the mechanical strength of the polymer. Conduction through the crystalline domain was never considered possible until the discovery of a PEO/salt co-crystal [PEO6], which was found to be more conductive than its amorphous counterpart. In PEO6 [the crystal structure co-crystallizes 6 PEO ether oxygens to one Li-anion pair], two PEO chains fold around Li+ in a non-helical fashion forming an approximate cylindrical "tunnel" with lithium atoms distributed along the cylinder central axis. Each lithium atom coordinates five ether oxygens; the anions are outside the tunnel and there is no direct bonding between the anions and the Li+. Due to its unique tunnel-like structure, PEO6 conducts Li+ based on a mechanism that decouples the conductivity and segmental motion of the polymer. However, these polymer electrolytes have not been used for battery applications because these studies used low molecular weight PEO (1000 g/mol) to achieve high crystallinity of the PEO6 phase. At this low molecular weight, the polymer does not confer the high modulus required. In SPEs with high molecular weight PEO, conduction through PEO6 is unfavorable as the tunnels fold to form lamellar structures and increase the conduction pathway. In this study, we explore conduction in high molecular weight [600000 g/mol] crystalline polymer electrolytes at EO: Li = 6:1. At this molecular weight, although four lithium salts [LiPF6, LiAsF6, LiSbF6, and LiClO4] can form PEO6, we focus our study on PEO6-LiClO4, which displays the highest conductivity than with other salt complexes. But this conductivity of PEO6LiClO4 drops by an order of magnitude after 2 months of thermal annealing. This is also accompanied by the changes in the XRD pattern which is uncharacteristic of any phases of PEO-LiClO4. Thus to explain this change, we explore the possibility of defects like vacancy, extra salt, and interstitial lithium in PEO6. In addition to being enthalpically stable, these defects also display the peculiar peaks of long-time annealed samples. While the change in the XRD pattern of a long-time annealed PEO6 can be explained by a combination of defects, based on their relative stability, it is more likely to be due to the "trapped" PEO6 structure. In this structure, in contrast to PEO6 where lithium atoms are at the center of the tunnel, one of the Li+ is "trapped" in the periphery of the tunnel coordinating with four ether oxygens and one anion, distorting the PEO6 tunnel. Because this crystal transformation is detrimental to conduction in PEO6, we use a percolated network of high aspect ratio fillers (cellulose nanowhiskers) to stabilize PEO6 tunnels over long distances. The patterned arrangement of the --OH surface group, which has a Lewis acidic character allows it to interact with either the anions or ether oxygen on the PEO chain. In addition, the distance between primary alcohol groups on the cellulose surface along the axial direction closely matches with the lattice parameter of PEO6 along the tunnel direction. This results in a low energy penalty [0.08 eV] for constraining PEO6 on the surface of the whisker, making it a suitable nucleation agent for PEO6LiClO4. Although these patterned cellulose nanowhiskers do stabilize PEO6 tunnels resulting in no change in XRD pattern even after a year of annealing, the room temperature conductivity (6 x10-6 S/cm) is still below the target value (10-3 S/cm). To improve the conductivity further, we draw inspiration from crystalline ceramic conductors, which have utilized doping [adding or substituting a small percentage of impurities to the host material] strategies to increase conductivity. By replacing 0.5-10% LiClO4 with NaClO4 in PEO6LiClO4, we demonstrate an order of magnitude increase in room temperature conductivity with the highest effect at 1% doping. This increase is not correlated with the glass transition temperature. Up to 1%, doping disrupts PEO6 crystallization. Above 1 %, diffraction peaks arise between 10-15o which cannot be due to PEO6 but resemble another polymer salt co-crystal, PEO3. A stable structure for PEO6 with NaClO4 is determined computationally, whereas only structures for PEO3 and PEO8 have been observed experimentally. Due to doping, larger sodium cations could either be accommodated into PEO6 or could end up not being part of the PEO6 lattice, resulting in a vacancy in PEO6. From DFT calculations, we determine that it is 0.92 eV more energetically favorable to swap sodium with lithium in PEO6 than to form PEO6 with vacancy. We conclude the increase in conductivity to be a consequence of weaker coordination of sodium to ether oxygen which increases the "bottleneck" size for conduction. In the sodium doping study, the presence of PEO3 peaks in XRD was correlated with increase an increase in conductivity. This is contrary to the popular belief that PEO3 is non-conductive. In contrast to PEO6, in PEO3, only one chain wraps around the Li+ in a helical fashion resulting in three-fold coordination of ether oxygen and two-fold coordination of anions. Due to tighter coordination of the lithium atoms with the neighboring anions, and lack of uncoordinated neighboring sites in PEO3, the activation energy for lithium hop as reported in PEO3LiCF3SO3 was found to be high [~1 eV]1-2, resulting in low ionic conductivity. If this gridlock is reduced by creating more vacancies, lithium atoms in PEO3 could become more mobile. To test this hypothesis, we create vacancies in PEO3 by reducing the concentration of LiClO4 from EO: Li = 3:1. We observe several orders of improvement in conductivity with a 20% reduction in salt concentration from EO: Li = 3:1, with no change in crystal structure or crystallinity up to 30% concentration deviation. Surprisingly, this change in conduction is accompanied by an increase in activation energy, indicating a change in the mechanism of conduction. To explain this change, we use DFT to find the activation energy for several conduction pathways in PEO3 including lithium diffusion: along the strand, across the strand, into a vacancy, and anion diffusion. In contrast to the previously held view that PEO3 has activation energy [~1eV], we conclude that the activation energy of PEO3LiClO4 can vary from 0.42- 1.3 eV depending on the conduction pathway. Thus, using both experiments and simulations we demonstrate the potential of crystalline polymer electrolytes and develop tools to understand the conduction mechanism in them. Although we did not reach the target conductivity, the findings from this work are important to design fast conduction solid polymer electrolytes.

Designing Electrolytes For Lithium Ion And Post Lithium Batteries

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Author : Władysław Wieczorek
language : en
Publisher: CRC Press
Release Date : 2021-06-23

Designing Electrolytes For Lithium Ion And Post Lithium Batteries written by Władysław Wieczorek and has been published by CRC Press this book supported file pdf, txt, epub, kindle and other format this book has been release on 2021-06-23 with Technology & Engineering categories.

Every electrochemical source of electric current is composed of two electrodes with an electrolyte in between. Since storage capacity depends predominantly on the composition and design of the electrodes, most research and development efforts have been focused on them. Considerably less attention has been paid to the electrolyte, a battery’s basic component. This book fills this gap and shines more light on the role of electrolytes in modern batteries. Today, limitations in lithium-ion batteries result from non-optimal properties of commercial electrolytes as well as scientific and engineering challenges related to novel electrolytes for improved lithium-ion as well as future post-lithium batteries.

Polymer Electrolytes

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Author : Fiona M. Gray
language : en
Publisher:
Release Date : 1997

Polymer Electrolytes written by Fiona M. Gray and has been published by this book supported file pdf, txt, epub, kindle and other format this book has been release on 1997 with Science categories.

The first book in the RSC Materials Monographs Series, Polymer Electrolytes brings together the latest research in this important subject. The emphasis is on practical materials and it includes an excellent classification of polymer electrolytes, a comprehensive look at material types and an important discussion of the commercial prospects. The text is designed for research workers from a variety of disciplines and looks at some of the history as well as the future of the subject, including reference to computer simulation. Overall, Polymer Electrolytes is an important review of the structural, physical and electrical properties of the materials which are competing for a place in the future energy generation, storage and distribution markets.

Crystalline Polymer Electrolytes

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Author : Edward John Staunton
language : en
Publisher:
Release Date : 2006

Crystalline Polymer Electrolytes written by Edward John Staunton and has been published by this book supported file pdf, txt, epub, kindle and other format this book has been release on 2006 with Crystalline polymers categories.

Crystalline Polymer And 3d Ceramic Polymer Electrolytes For Li Ion Batteries

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Author : Aleksandra K. Hekselman
language : en
Publisher:
Release Date : 2014

Crystalline Polymer And 3d Ceramic Polymer Electrolytes For Li Ion Batteries written by Aleksandra K. Hekselman and has been published by this book supported file pdf, txt, epub, kindle and other format this book has been release on 2014 with Crystalline polymers categories.

Polymerized Ionic Liquids

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Author : Ali Eftekhari
language : en
Publisher: Royal Society of Chemistry
Release Date : 2017-09-18

Polymerized Ionic Liquids written by Ali Eftekhari and has been published by Royal Society of Chemistry this book supported file pdf, txt, epub, kindle and other format this book has been release on 2017-09-18 with Addition polymerization categories.

The applications of ionic liquids can be enormously expanded by arranging the organic ions in the form a polymer architecture. Polymerized ionic liquids (PILs), also known as poly(ionic liquid)s or polymeric ionic liquids, provide almost all features of ionic polymers plus a rare versatility in design. Written by leading authors, the present book provides a comprehensive overview of this exciting area, discussing various aspects of PILs and their applications as smart materials. The book will appeal to a broad readership including students and researchers from materials science, polymer science, chemistry, and physics.