Polymer Electrolytes for Rechargeable Lithium/sulfur Batteries PDF Download
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Author: Kazem Jeddi
Publisher:
ISBN:
Category :
Languages : en
Pages : 97
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Book Description
The lithium/sulfur (Li/S) battery is one of the most promising candidates for energy storage systems due to sulfur's high theoretical specific capacity at 1672 mAh g-1. This capacity is an order of magnitude higher than that of conventional electrodes and gives packaged Li/S cells an energy density of 400-600 W h kg-1, which is two or three times higher than that of current lithium-ion batteries. In addition, low cost, abundance and environmental friendliness of sulfur offer the opportunity to produce cheap, safe and commercializable high-energy density batteries. Despite these advantages, the practical application of Li/S batteries is still prevented by modest practical capacity, short cycle life and low Coulombic efficiency. These problems are mainly due to:(i) low electronic conductivity of sulfur, which leads to low sulfur utilization; (ii) generation of various forms of soluble intermediate lithium polysulfides during the electrochemical reactions, which dissolve in the electrolyte and induce the so-called shuttle effect causing irreversible loss of sulfur active material over repeat cycles; (iii) volume change of sulfur upon cycling, which leads to its mechanical rupture and, consequently, rapid degradation of the electrochemical performance. Since the early development of Li/S batteries by Abraham and Peled in the 1980s, a large number of studies have been done to understand the electrochemical mechanism of the Li/S cell and overcome its drawbacks. Studies have focused on increasing the electronic conductivity of sulfur by encapsulating sulfur with conducting materials such as porous carbon or conductive polymers, and suppressing polysulfide dissolution into the liquid electrolyte by coating with conductive polymers and oxides. It should be pointed out that most of the research efforts to improve the performance of Li/S batteries have focused on the cathode electrode. From the electrolyte perspective, the use of conventional liquid electrolytes deteriorates battery performance due to polysulfide dissolution and their shuttle between cathode and anode that leads to fast capacity degradation and low Coulombic efficiency. Moreover, the use of these liquid electrolytes raises safety concerns since they are prone to leakage and safety hazard. The motivation for this PhD work is to search for better electrolyte systems for Li/S batteries. We aim to study the effect of these electrolytes on the performance of Li/S batteries in conjunction with designed cathode materials using sulfur/conductive polymer and sulfur/carbon composites. In the first part of the thesis, we introduce gel polymer electrolytes (GPEs) into Li/S batteries with sulfur-polyacrylonitrile (S/PAN) composite cathodes. GPEs, consisting of solid matrices and embedded liquid electrolytes, may generally be defined as a polymer membrane that possesses ionic transport properties comparable to that of liquid electrolytes. In particular, for Li/S batteries, it is expected that the polymer membrane can act as a physical barrier, which can help control the dissolution of the polysulfide anions from the cathode and also prevent their migration to the anode. Specifically, the GPE was formed by trapping solutions of lithium hexafluorophosphate (LiPF6) in ethylene carbonate electrolyte in a poly(vinylidene fluoride-co-hexafluoropropylene) (PVdF-HFP)-based polymer matrix. However, these Li/GPE/S cells suffer from performance fade after a few cycles due to the inability to retain liquid electrolyte in the GPE. A wide variety of methods were studied in order to improve the stability of the GPE and the performance of Li/S cells, including incorporation of layered nanoparticles, synthesis and addition of functionalized polymers and synthesis and addition of mesoporous nanoparticles. It was observed that incorporation of organically modified nanoparticles (OMMT) or functional polymer bearing inorganic domains reduces the pore size and improves the uniformity of pore size in the PVdF-HFP membrane, which prevents the release of electrolyte solution during cycling and suppresses the dissolution of polysulfides. The Li/S cell with the PVdF-HFP/OMMT nanocomposite electrolyte delivered an initial capacity of 1622 mAh g-1 and maintained a capacity of 500 mAh g-1 after 300 cycles. When the PVdF-HFP/functionalized PMMA electrolyte was used, the Li/S battery had an initial discharge capacity of 1600 mAh g-1 and a stable capacity of 1050 mAh g-1 after more than 100 cycles. Furthermore, utilization of the PVdF-HFP/functionalized PMMA/mesoporous silica composite electrolyte resulted in an initial discharge capacity of 1648 mAh g-1 and a stable discharge capacity of 1143 mAh g-1 after more than 100 cycles. The preparation procedures employed have the advantage of being reproducible, simple and inexpensive. In the second part of the thesis, gel polymer electrolyte systems were prepared and tested in Li/S batteries with sulfur/carbon (S/C) composite cathodes. Sulfur/carbon (S/C) composite cathodes are of great interest since they potentially offer higher loading of sulfur (>60 wt%). However, severe capacity fading and low cycling efficiency due to lithium polyslfide dissolution and diffusion result in poor cyclability. Therefore, it is difficult to find a suitable electrolyte for this category of sulfur-based composite cathodes. The high-energy and low-cost S/C composite cathode was synthesized through a facile one-step solution processing method, in which activated hardwood charcoal (AHC) powder was used as a scaffold to embed the sulfur active material and improve its electronic conductivity and its utilization in the battery cell. Results showed that normal gel polymer electrolytes could not effectively prevent polysulfide dissolution and performance fading. However, when a fluorinated liquid electrolyte containing1,1,2,2-tetrafluoroethyl-2,2,3,3-tetrafluoropropyl ether was employed, a significant improvement in the electrochemical performance of the Li/S cell was achieved. It was observed that such a low-cost Li/S cell can be operated for more than 300 cycles while still maintaining high specific capacity (600 mAh g-1) and 97% Coulombic efficiency. Further analyses confirmed that such an enhanced performance was due to the confinement of lithium polysulfides inside the cathode electrode that prevented their shuttling between cathode and anode. This minimized the severe active mass loss that leads to fast capacity degradation and low Coulombic efficiency. The electrochemical performance of this new Li/S battery configuration represents a significant improvement in comparison to that of conventional electrolytes under the same testing conditions.
Author: Kazem Jeddi
Publisher:
ISBN:
Category :
Languages : en
Pages : 97
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Book Description
The lithium/sulfur (Li/S) battery is one of the most promising candidates for energy storage systems due to sulfur's high theoretical specific capacity at 1672 mAh g-1. This capacity is an order of magnitude higher than that of conventional electrodes and gives packaged Li/S cells an energy density of 400-600 W h kg-1, which is two or three times higher than that of current lithium-ion batteries. In addition, low cost, abundance and environmental friendliness of sulfur offer the opportunity to produce cheap, safe and commercializable high-energy density batteries. Despite these advantages, the practical application of Li/S batteries is still prevented by modest practical capacity, short cycle life and low Coulombic efficiency. These problems are mainly due to:(i) low electronic conductivity of sulfur, which leads to low sulfur utilization; (ii) generation of various forms of soluble intermediate lithium polysulfides during the electrochemical reactions, which dissolve in the electrolyte and induce the so-called shuttle effect causing irreversible loss of sulfur active material over repeat cycles; (iii) volume change of sulfur upon cycling, which leads to its mechanical rupture and, consequently, rapid degradation of the electrochemical performance. Since the early development of Li/S batteries by Abraham and Peled in the 1980s, a large number of studies have been done to understand the electrochemical mechanism of the Li/S cell and overcome its drawbacks. Studies have focused on increasing the electronic conductivity of sulfur by encapsulating sulfur with conducting materials such as porous carbon or conductive polymers, and suppressing polysulfide dissolution into the liquid electrolyte by coating with conductive polymers and oxides. It should be pointed out that most of the research efforts to improve the performance of Li/S batteries have focused on the cathode electrode. From the electrolyte perspective, the use of conventional liquid electrolytes deteriorates battery performance due to polysulfide dissolution and their shuttle between cathode and anode that leads to fast capacity degradation and low Coulombic efficiency. Moreover, the use of these liquid electrolytes raises safety concerns since they are prone to leakage and safety hazard. The motivation for this PhD work is to search for better electrolyte systems for Li/S batteries. We aim to study the effect of these electrolytes on the performance of Li/S batteries in conjunction with designed cathode materials using sulfur/conductive polymer and sulfur/carbon composites. In the first part of the thesis, we introduce gel polymer electrolytes (GPEs) into Li/S batteries with sulfur-polyacrylonitrile (S/PAN) composite cathodes. GPEs, consisting of solid matrices and embedded liquid electrolytes, may generally be defined as a polymer membrane that possesses ionic transport properties comparable to that of liquid electrolytes. In particular, for Li/S batteries, it is expected that the polymer membrane can act as a physical barrier, which can help control the dissolution of the polysulfide anions from the cathode and also prevent their migration to the anode. Specifically, the GPE was formed by trapping solutions of lithium hexafluorophosphate (LiPF6) in ethylene carbonate electrolyte in a poly(vinylidene fluoride-co-hexafluoropropylene) (PVdF-HFP)-based polymer matrix. However, these Li/GPE/S cells suffer from performance fade after a few cycles due to the inability to retain liquid electrolyte in the GPE. A wide variety of methods were studied in order to improve the stability of the GPE and the performance of Li/S cells, including incorporation of layered nanoparticles, synthesis and addition of functionalized polymers and synthesis and addition of mesoporous nanoparticles. It was observed that incorporation of organically modified nanoparticles (OMMT) or functional polymer bearing inorganic domains reduces the pore size and improves the uniformity of pore size in the PVdF-HFP membrane, which prevents the release of electrolyte solution during cycling and suppresses the dissolution of polysulfides. The Li/S cell with the PVdF-HFP/OMMT nanocomposite electrolyte delivered an initial capacity of 1622 mAh g-1 and maintained a capacity of 500 mAh g-1 after 300 cycles. When the PVdF-HFP/functionalized PMMA electrolyte was used, the Li/S battery had an initial discharge capacity of 1600 mAh g-1 and a stable capacity of 1050 mAh g-1 after more than 100 cycles. Furthermore, utilization of the PVdF-HFP/functionalized PMMA/mesoporous silica composite electrolyte resulted in an initial discharge capacity of 1648 mAh g-1 and a stable discharge capacity of 1143 mAh g-1 after more than 100 cycles. The preparation procedures employed have the advantage of being reproducible, simple and inexpensive. In the second part of the thesis, gel polymer electrolyte systems were prepared and tested in Li/S batteries with sulfur/carbon (S/C) composite cathodes. Sulfur/carbon (S/C) composite cathodes are of great interest since they potentially offer higher loading of sulfur (>60 wt%). However, severe capacity fading and low cycling efficiency due to lithium polyslfide dissolution and diffusion result in poor cyclability. Therefore, it is difficult to find a suitable electrolyte for this category of sulfur-based composite cathodes. The high-energy and low-cost S/C composite cathode was synthesized through a facile one-step solution processing method, in which activated hardwood charcoal (AHC) powder was used as a scaffold to embed the sulfur active material and improve its electronic conductivity and its utilization in the battery cell. Results showed that normal gel polymer electrolytes could not effectively prevent polysulfide dissolution and performance fading. However, when a fluorinated liquid electrolyte containing1,1,2,2-tetrafluoroethyl-2,2,3,3-tetrafluoropropyl ether was employed, a significant improvement in the electrochemical performance of the Li/S cell was achieved. It was observed that such a low-cost Li/S cell can be operated for more than 300 cycles while still maintaining high specific capacity (600 mAh g-1) and 97% Coulombic efficiency. Further analyses confirmed that such an enhanced performance was due to the confinement of lithium polysulfides inside the cathode electrode that prevented their shuttling between cathode and anode. This minimized the severe active mass loss that leads to fast capacity degradation and low Coulombic efficiency. The electrochemical performance of this new Li/S battery configuration represents a significant improvement in comparison to that of conventional electrolytes under the same testing conditions.
Author: Yan Zhao
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
With the rapid development of portable electronics, hybrid-electric and electric cars, there is great interest in utilization of sulfur as cathodes for rechargeable lithium batteries. Lithium/sulfur batteries implement inexpensive, the earth-abundant elements at the cathode while offering up to a five-fold increase in energy density compared with the present Li-ion batteries. However, electrically insulating character of sulfur and solubility of intermediate polysulfides in organic liquid electrolytes, which causes rapid capacity loss upon repeated cycling, restrict the practical application of Li/S batteries. In this thesis, the gel polymer and solid polymer electrolytes were synthesized and applied in Li/S batteries.
Author: Mark Wild
Publisher: John Wiley & Sons
ISBN: 1119297869
Category : Technology & Engineering
Languages : en
Pages : 349
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Book Description
A guide to lithium sulfur batteries that explores their materials, electrochemical mechanisms and modelling and includes recent scientific developments Lithium Sulfur Batteries (Li-S) offers a comprehensive examination of Li-S batteries from the viewpoint of the materials used in their construction, the underlying electrochemical mechanisms and how this translates into the characteristics of Li-S batteries. The authors – noted experts in the field – outline the approaches and techniques required to model Li-S batteries. Lithium Sulfur Batteries reviews the application of Li-S batteries for commercial use and explores many broader issues including the development of battery management systems to control the unique characteristics of Li-S batteries. The authors include information onsulfur cathodes, electrolytes and other components used in making Li-S batteries and examine the role of lithium sulfide, the shuttle mechanism and its effects, and degradation mechanisms. The book contains a review of battery design and: Discusses electrochemistry of Li-S batteries and the analytical techniques used to study Li-S batteries Offers information on the application of Li-S batteries for commercial use Distills years of research on Li-S batteries into one comprehensive volume Includes contributions from many leading scientists in the field of Li-S batteries Explores the potential of Li-S batteries to power larger battery applications such as automobiles, aviation and space vehicles Written for academic researchers, industrial scientists and engineers with an interest in the research, development, manufacture and application of next generation battery technologies, Lithium Sulfur Batteries is an essential resource for accessing information on the construction and application of Li-S batteries.
Author:
Publisher:
ISBN:
Category :
Languages : en
Pages : 20
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Book Description
SRI International has synthesized and tested new, dimensionally stable polymer electrolytes for high energy density rechargeable lithium batteries. We have prepared semi-interpenetrating networks of sulfur-substituted polyethyleneoxide with tetmethylorthosilicate (TEOS). The in situ hydrolysis of TEOS produces a mechanically stable three-dimensional network that entangles the polymer electrolytes and makes the film dimensionally flexible and stable. With this approach, the best dimensionally stable polymer electrolyte of this type produced so far, has a room temperature lithium ion conductivity of 7.5 x 10−4 S cm−1. Another type of solid polymer electrolytes, polydiacetylene-based single-ion conductors with high room temperature proton conductivity were also developed. The best conductivity of these polymers is two orders of magnitude higher than that of Nafion under comparable experimental conditions. With further appropriate chemical modification, the new polymers could be used in fuel cells.
Author: Ram Gupta
Publisher: Elsevier
ISBN: 0323919324
Category : Technology & Engineering
Languages : en
Pages : 710
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Book Description
Lithium-Sulfur Batteries: Materials, Challenges, and Applications presents the advantages of lithium-sulfur batteries, such as high theoretical capacity, low cost, and stability, while also addressing some of the existing challenges. Some of the challenges are low electrical conductivity, the possible reaction of sulfur with lithium to form a soluble lithium salt, the formation of the dendrimer, large volume variation of cathode materials during the electrochemical reaction, and shuttle behavior of highly soluble intermediate polysulfides in the electrolyte. This book provides some possible solutions to these issues through novel architecture, using composite materials, doping to improve low conductivity, etc., as well as emphasizing novel materials, architectural concepts, and methods to improve the performance of lithium-sulfur batteries. - Covers the state-of-the-art progress on materials, technology, and challenges for lithium-sulfur batteries - Presents novel synthetic approaches, characterizations, and applications of nanostructured and 2D nanomaterials for energy applications - Provides fundamentals of electrochemical behavior and their understanding at nanoscale for emerging applications in lithium-sulfur batteries
Author: Daniel Brandell
Publisher: Walter de Gruyter GmbH & Co KG
ISBN: 1501514903
Category : Technology & Engineering
Languages : en
Pages : 236
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Book Description
Recent years has seen a tremendous growth in interest for solid state batteries based on polymer electrolytes, with advantages of higher safety, energy density, and ease of processing. The book explains which polymer properties guide the performance of the solid-state device, and how these properties are best determined. It is an excellent guide for students, newcomers and experts in the area of solid polymer electrolytes.
Author: Alejandro Franco
Publisher: Elsevier
ISBN: 1782420983
Category : Technology & Engineering
Languages : en
Pages : 413
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Book Description
Rechargeable Lithium Batteries: From Fundamentals to Application provides an overview of rechargeable lithium batteries, from fundamental materials, though characterization and modeling, to applications. The market share of lithium ion batteries is fast increasing due to their high energy density and low maintenance requirements. Lithium air batteries have the potential for even higher energy densities, a requirement for the development of electric vehicles, and other types of rechargeable lithium battery are also in development. After an introductory chapter providing an overview of the main scientific and technological challenges posed by rechargeable Li batteries, Part One of this book reviews materials and characterization of rechargeable lithium batteries. Part Two covers performance and applications, discussing essential aspects such as battery management, battery safety and emerging rechargeable lithium battery technologies as well as medical and aerospace applications. - Expert overview of the main scientific and technological challenges posed by rechargeable lithium batteries - Address the important topics of analysis, characterization, and modeling in rechargeable lithium batteries - Key analysis of essential aspects such as battery management, battery safety, and emerging rechargeable lithium battery technologies
Author: Krzysztof Jan Siczek
Publisher: Academic Press
ISBN: 0128166126
Category : Technology & Engineering
Languages : en
Pages : 262
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Book Description
Next-Generation Batteries with Sulfur Cathodes provides a comprehensive review of a modern class of batteries with sulfur cathodes, particularly lithium-sulfur cathodes. The book covers recent trends, advantages and disadvantages in Li-S, Na-S, Al-S and Mg-S batteries and why these batteries are very promising for applications in hybrid and electric vehicles. Battery materials and modelling are also dealt with, as is their design, the physical phenomena existing in batteries, and a comparison of batteries between commonly used lithium-ion batteries and the new class of batteries with sulfur cathodes that are useful for devices like vehicles, wind power aggregates, computers and measurement units. - Provides solutions for the recycling of batteries with sulfur cathodes - Includes the effects of analysis and pro and cons of Li-S, Na-S, Al-S, Mg-S and Zn-S batteries - Describes state-of-the-art technological developments and possible applications
Author: Vladimir Neburchilov
Publisher: CRC Press
ISBN: 1482258544
Category : Science
Languages : en
Pages : 210
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Book Description
Metal–air and metal–sulfur batteries (MABs/MSBs) represent one of the most efficient-energy storage technologies, with high round trip efficiency, a long life cycle, fast response at peak demand/supply of electricity, and decreased weight due to the use of atmospheric oxygen as one of the main reactants. This book presents an overview of the main MABs/MSBs from fundamentals to applications. Recent technological trends in their development are reviewed. It also offers a detailed analysis of these batteries at the material, component, and system levels, allowing the reader to evaluate the different approaches of their integration. The book provides a systematic overview of the components, design, and integration, and discusses current technologies, achievements, and challenges, as well as future directions. Each chapter focuses on a particular battery type including zinc–air batteries, lithium–air batteries, aluminum–air batteries, magnesium–air batteries, lithium–sulfur batteries, and vanadium–air redox flow batteries, and metal–sulfur batteries. Features the most recent advances made in metal–air/metal–sulfur batteries. Describes cutting-edge materials and technology for metal–air/metal–sulfur batteries. Includes both fundamentals and applications, which can be used to guide and promote materials as well as technology development for metal–air/metal–sulfur batteries. Provides a systematic overview of the components, design, and integration, and discusses current technologies, achievements, and challenges, as well as future directions. Covers a variety of battery types in depth, such as zinc–air batteries, lithium–air batteries, aluminum–air batteries, magnesium–air batteries, lithium–sulfur batteries, vanadium–air redox flow batteries, and metal–sulfur batteries.
Author: Władysław Wieczorek
Publisher: CRC Press
ISBN: 1000076806
Category : Technology & Engineering
Languages : en
Pages : 345
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Book Description
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.
