Polyethylene Glycol as an Electrolyte Additive for Rechargeable Hybrid Aqueous Batteries PDF Download
Are you looking for read ebook online? Search for your book and save it on your Kindle device, PC, phones or tablets. Download Polyethylene Glycol as an Electrolyte Additive for Rechargeable Hybrid Aqueous Batteries PDF full book. Access full book title Polyethylene Glycol as an Electrolyte Additive for Rechargeable Hybrid Aqueous Batteries by Aly Mitha. Download full books in PDF and EPUB format.
Author: Aly Mitha
Publisher:
ISBN:
Category : Electrolytes
Languages : en
Pages : 100
Get Book Here
Book Description
Climatic and environmental challenges arising from excessive greenhouse gas production from human activities have necessitated a serious shift towards sustainable and renewable sources of power such as solar, wind and tidal. The bottleneck hindering the wide-scale adoption of these technologies is the intermittency of available power due to non-uniform climate and weather patterns over the course of the year. These variations prevent renewable energies from sustaining entire economies independently. Presently, secondary power generation must be run in parallel to sustain the base load while renewables are used to meet excess demand during peak load. Batteries are the strongest candidates for the improvement of these systems. They have been applied to enable load-levelling by storing excess power produced and supplying it to the grid during high demand periods. Aqueous metal ion batteries are a strong contender for energy storage from renewable power sources due to their excellent safety, low cost, and environmental friendliness. In 2012, our research team developed the Rechargeable Hybrid Aqueous Battery (ReHAB) which featured a lithiated manganese oxide cathode and a zinc foil anode. While this battery generally performs well, it is compromised by parasitic processes at the anode which decrease its performance and operational lifespan. The main failure modes of this system are runaway dendrite formation from non-uniform electrodeposition and a high degree of corrosion caused by the acidic environment. In this research, polyethylene glycol is integrated into the ReHAB system. The hypothesis is that PEG can be used to inhibit corrosion and dendritic growth. Low molecular weights (less than 500 g.mol-1) are used due to their greater solubility in the sulfate-based electrolyte. In the first project, 1 vol.% PEG200 is able to improve the discharge capacity of ReHAB cells compared to the control electrolyte after 300 cycles. This is accomplished via minimizing corrosion and dendrite growth at the anode. Furthermore, when dendrites are pre-grown on the anode prior to battery testing, the 1 vol.% PEG200 cells are able to consistently improve cycling life by more than five times. In the second project a novel gel electrolyte is developed for the ReHAB system to improve cycling performance, reliability and reduce leakage of electrolyte during processing. Fumed silica is used as the thixotropic gelling agent and forms an interconnected network to support aqueous media in the electrolyte. PEG300 is used as the corrosion inhibitor and dendrite suppressant. The developed PEG-FS gel decreases corrosion by up to 40% and dendrite growth rate by 78%. In the absence of the PEG-FS gel electrolyte the zinc anode was severely consumed by corrosion reactions. Additionally, the PEG-FS-gel increases the capacity retention of ReHAB cells by approximately 40% after 1000 cycles in the large battery system. The mechanism of interaction between PEG polymers and the zinc anode are also examined in depth using various electrochemical, spectroscopic and microscopic techniques. PEG adsorbs to the anode surface during charging and subsequently desorbs during discharge. PEG polymers were found to specifically adsorb to preferential nucleation sites on the zinc electrode, leading to several beneficial effects. Firstly, the surface diffusion of zinc ions is decreased, and they are forced to deposit on less favored sites on the electrode surface, leading to controlled electrodeposition. Secondly, the PEG polymers obstruct the adsorption of hydrogen ions during the charging process, thus decreasing corrosion and hydrogen evolution reactions. The adsorption-desorption mechanism allows the PEG to be recycled during battery operation and remain effective for very long periods. Overall, highly compelling improvements are made to the ReHAB system with the addition of PEG to the aqueous electrolyte. By subduing corrosion and dendrite formation, the utilization of lithium is improved more than five-fold. This is a serious contribution as it allows for a much more efficient use of increasingly rare resources. The merits of PEG combined with its ease of integration into current aqueous battery systems highlights how they can be made into viable alternatives to lead-acid and organic lithium ion batteries for large scale energy storage applications.
Author: Aly Mitha
Publisher:
ISBN:
Category : Electrolytes
Languages : en
Pages : 100
Get Book Here
Book Description
Climatic and environmental challenges arising from excessive greenhouse gas production from human activities have necessitated a serious shift towards sustainable and renewable sources of power such as solar, wind and tidal. The bottleneck hindering the wide-scale adoption of these technologies is the intermittency of available power due to non-uniform climate and weather patterns over the course of the year. These variations prevent renewable energies from sustaining entire economies independently. Presently, secondary power generation must be run in parallel to sustain the base load while renewables are used to meet excess demand during peak load. Batteries are the strongest candidates for the improvement of these systems. They have been applied to enable load-levelling by storing excess power produced and supplying it to the grid during high demand periods. Aqueous metal ion batteries are a strong contender for energy storage from renewable power sources due to their excellent safety, low cost, and environmental friendliness. In 2012, our research team developed the Rechargeable Hybrid Aqueous Battery (ReHAB) which featured a lithiated manganese oxide cathode and a zinc foil anode. While this battery generally performs well, it is compromised by parasitic processes at the anode which decrease its performance and operational lifespan. The main failure modes of this system are runaway dendrite formation from non-uniform electrodeposition and a high degree of corrosion caused by the acidic environment. In this research, polyethylene glycol is integrated into the ReHAB system. The hypothesis is that PEG can be used to inhibit corrosion and dendritic growth. Low molecular weights (less than 500 g.mol-1) are used due to their greater solubility in the sulfate-based electrolyte. In the first project, 1 vol.% PEG200 is able to improve the discharge capacity of ReHAB cells compared to the control electrolyte after 300 cycles. This is accomplished via minimizing corrosion and dendrite growth at the anode. Furthermore, when dendrites are pre-grown on the anode prior to battery testing, the 1 vol.% PEG200 cells are able to consistently improve cycling life by more than five times. In the second project a novel gel electrolyte is developed for the ReHAB system to improve cycling performance, reliability and reduce leakage of electrolyte during processing. Fumed silica is used as the thixotropic gelling agent and forms an interconnected network to support aqueous media in the electrolyte. PEG300 is used as the corrosion inhibitor and dendrite suppressant. The developed PEG-FS gel decreases corrosion by up to 40% and dendrite growth rate by 78%. In the absence of the PEG-FS gel electrolyte the zinc anode was severely consumed by corrosion reactions. Additionally, the PEG-FS-gel increases the capacity retention of ReHAB cells by approximately 40% after 1000 cycles in the large battery system. The mechanism of interaction between PEG polymers and the zinc anode are also examined in depth using various electrochemical, spectroscopic and microscopic techniques. PEG adsorbs to the anode surface during charging and subsequently desorbs during discharge. PEG polymers were found to specifically adsorb to preferential nucleation sites on the zinc electrode, leading to several beneficial effects. Firstly, the surface diffusion of zinc ions is decreased, and they are forced to deposit on less favored sites on the electrode surface, leading to controlled electrodeposition. Secondly, the PEG polymers obstruct the adsorption of hydrogen ions during the charging process, thus decreasing corrosion and hydrogen evolution reactions. The adsorption-desorption mechanism allows the PEG to be recycled during battery operation and remain effective for very long periods. Overall, highly compelling improvements are made to the ReHAB system with the addition of PEG to the aqueous electrolyte. By subduing corrosion and dendrite formation, the utilization of lithium is improved more than five-fold. This is a serious contribution as it allows for a much more efficient use of increasingly rare resources. The merits of PEG combined with its ease of integration into current aqueous battery systems highlights how they can be made into viable alternatives to lead-acid and organic lithium ion batteries for large scale energy storage applications.
Author: Kai Zhu
Publisher: Frontiers Media SA
ISBN: 2889668193
Category : Science
Languages : en
Pages : 134
Get Book Here
Book Description
Author: Du Yuan
Publisher: Frontiers Media SA
ISBN: 2889663760
Category : Science
Languages : en
Pages : 96
Get Book Here
Book Description
Author: Ziyin Huang
Publisher:
ISBN:
Category : Crosslinked polymers
Languages : en
Pages : 200
Get Book Here
Book Description
Lithium metal batteries, which use lithium metal as the anode, have the advantage of much higher energy density over the commercially used lithium-ion batteries with graphite as the anode. However, during repeated charge-discharge cycles, lithium dendrites may form due to uneven deposition of lithium on the lithium metal anode, and lithium dendrite growth induced short-circuits are always a problem preventing lithium-metal batteries from being used in a lot of applications. Using solid polymer electrolyte (SPE) for lithium metal batteries has the benefit of using the electrolyte as the electrode separator while inhibiting the growth of lithium dendrites. The current most significant issue for SPEs is low ionic conductivity at room temperature. Poly(ethylene glycol) (PEG) has been extensively used for SPE systems due to its strong lithium ion solvating ability and high dielectric constant. In this study, crosslinked PEG polymer electrolyte membranes were synthesized with different amount of plasticizers to produce samples with different ionic conductivities and mechanical properties. It was shown that, with the increase amount of small PEG molecules added, the ionic conductivities of the SPEs showed significant increase and mechanical properties decreases. Performance of the electrolytes was correlated with both properties, and the results were analyzed to propose the ideal design for PEG polymer electrolytes for lithium metal polymer batteries.
Author: Nobuyuki Imanishi
Publisher: Springer Science & Business Media
ISBN: 1489980628
Category : Technology & Engineering
Languages : en
Pages : 327
Get Book Here
Book Description
Lithium air rechargeable batteries are the best candidate for a power source for electric vehicles, because of their high specific energy density. In this book, the history, scientific background, status and prospects of the lithium air system are introduced by specialists in the field. This book will contain the basics, current statuses, and prospects for new technologies. This book is ideal for those interested in electrochemistry, energy storage, and materials science.
Author: Patrick T. Moseley
Publisher: Newnes
ISBN: 0444626107
Category : Technology & Engineering
Languages : en
Pages : 493
Get Book Here
Book Description
Electricity from renewable sources of energy is plagued by fluctuations (due to variations in wind strength or the intensity of insolation) resulting in a lack of stability if the energy supplied from such sources is used in 'real time'. An important solution to this problem is to store the energy electrochemically (in a secondary battery or in hydrogen and its derivatives) and to make use of it in a controlled fashion at some time after it has been initially gathered and stored. Electrochemical battery storage systems are the major technologies for decentralized storage systems and hydrogen is the only solution for long-term storage systems to provide energy during extended periods of low wind speeds or solar insolation. Future electricity grid design has to include storage systems as a major component for grid stability and for security of supply. The technology of systems designed to achieve this regulation of the supply of renewable energy, and a survey of the markets that they will serve, is the subject of this book. It includes economic aspects to guide the development of technology in the right direction. - Provides state-of-the-art information on all of the storage systems together with an assessment of competing technologies - Features detailed technical, economic and environmental impact information of different storage systems - Contains information about the challenges that must be faced for batteries and hydrogen-storage to be used in conjunction with a fluctuating (renewable energy) power supply
Author: Ali Eftekhari
Publisher: Royal Society of Chemistry
ISBN: 1782629602
Category : Science
Languages : en
Pages : 564
Get Book Here
Book Description
The series covers the fundamentals and applications of different smart material systems from renowned international experts.
Author: Haiyan Wang
Publisher: John Wiley & Sons
ISBN: 352734974X
Category : Technology & Engineering
Languages : en
Pages : 341
Get Book Here
Book Description
Aqueous Zinc Ion Batteries Pioneering reference book providing the latest developments and experimental results of aqueous zinc ion batteries Aqueous Zinc Ion Batteries comprehensively reviews latest advances in aqueous zinc ion batteries and clarifies the relationships between issues and solutions for the emerging battery technology. Starting with the history, the text covers essentials of each component of aqueous zinc ion batteries, including cathodes, anodes, and electrolytes, helping readers quickly attain a foundational understanding of the subject. Written by three highly qualified authors with significant experience in the field, Aqueous Zinc Ion Batteries provides in-depth coverage of sample topics such as: History, main challenges, and zinc metal anodes for aqueous zinc ion batteries Electrochemical reaction mechanism of aqueous zinc ion batteries and interfacial plating and stripping on zinc anodes Cathode materials for aqueous zinc ion batteries, covering manganese-based materials, vanadium-based materials, Prussian blue analogs, and other cathode materials Development of electrolytes, issues, and corresponding solutions for aqueous zinc ion batteries Separators for aqueous zinc ion batteries, development of full zinc ion batteries, and future perspectives on the technology A detailed resource on a promising alternative to current lithium-ion battery systems, Aqueous Zinc Ion Batteries is an essential read for materials scientists, electrochemists, inorganic chemists, surface chemists, catalytic chemists, and surface physicists who want to be on the cutting edge of a promising new type of battery technology.
Author: Senentxu Lanceros-Méndez
Publisher: John Wiley & Sons
ISBN: 1119287421
Category : Technology & Engineering
Languages : en
Pages : 270
Get Book Here
Book Description
Offers the first comprehensive account of this interesting and growing research field Printed Batteries: Materials, Technologies and Applications reviews the current state of the art for printed batteries, discussing the different types and materials, and describing the printing techniques. It addresses the main applications that are being developed for printed batteries as well as the major advantages and remaining challenges that exist in this rapidly evolving area of research. It is the first book on printed batteries that seeks to promote a deeper understanding of this increasingly relevant research and application area. It is written in a way so as to interest and motivate readers to tackle the many challenges that lie ahead so that the entire research community can provide the world with a bright, innovative future in the area of printed batteries. Topics covered in Printed Batteries include, Printed Batteries: Definition, Types and Advantages; Printing Techniques for Batteries, Including 3D Printing; Inks Formulation and Properties for Printing Techniques; Rheological Properties for Electrode Slurry; Solid Polymer Electrolytes for Printed Batteries; Printed Battery Design; and Printed Battery Applications. Covers everything readers need to know about the materials and techniques required for printed batteries Informs on the applications for printed batteries and what the benefits are Discusses the challenges that lie ahead as innovators continue with their research Printed Batteries: Materials, Technologies and Applications is a unique and informative book that will appeal to academic researchers, industrial scientists, and engineers working in the areas of sensors, actuators, energy storage, and printed electronics.
Author: T. Richard Jow
Publisher: Springer
ISBN: 1493903020
Category : Technology & Engineering
Languages : en
Pages : 488
Get Book Here
Book Description
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.
