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| Author | : Albert R. Landgrebe |
| Publisher | : The Electrochemical Society |
| Total Pages | : 370 |
| Release | : 2001 |
| Genre | : Science |
| ISBN | : 9781566773058 |
| Author | : Andrea Paolella |
| Publisher | : Springer Nature |
| Total Pages | : 120 |
| Release | : |
| Genre | : |
| ISBN | : 3031637135 |
| Author | : Yaser Abu-Lebdeh |
| Publisher | : Springer Science & Business Media |
| Total Pages | : 288 |
| Release | : 2012-10-17 |
| Genre | : Science |
| ISBN | : 146144604X |
This unique combined analysis of two scientific success stories—lithium-ion batteries and nanotechnology—has contributions from leading international experts who analyze the positive interplay between them, as well as future developments in energy storage.
| Author | : Qiang Zhen |
| Publisher | : Springer Nature |
| Total Pages | : 472 |
| Release | : 2019-10-10 |
| Genre | : Technology & Engineering |
| ISBN | : 3662586754 |
Volume 3 of a 4-volume series is a concise, authoritative and an eminently readable and enjoyable experience related to lithium ion battery design, characterization and usage for portable and stationary power. Although the major focus is on lithium metal oxides or transition metal oxide as alloys, the discussion of fossil fuels is also presented where appropriate. This monograph is written by recognized experts in the field, and is both timely and appropriate as this decade will see application of lithium as an energy carrier, for example in the transportation sector. This Volume focuses on the fundamentals related to batteries using the latest research in the field of battery physics, chemistry, and electrochemistry. The research summarised in this book by leading experts is laid out in an easy-to-understand format to enable the layperson to grasp the essence of the technology, its pitfalls and current challenges in high-power Lithium battery research. After introductory remarks on policy and battery safety, a series of monographs are offered related to fundamentals of lithium batteries, including, theoretical modeling, simulation and experimental techniques used to characterize electrode materials, both at the material composition, and also at the device level. The different properties specific to each component of the batteries are discussed in order to offer tradeoffs between power and energy density, energy cycling, safety and where appropriate end-of-life disposal. Parameters affecting battery performance and cost, longevity using newer metal oxides, different electrolytes are also reviewed in the context of safety concerns and in relation to the solid-electrolyte interface. Separators, membranes, solid-state electrolytes, and electrolyte additives are also reviewed in light of safety, recycling, and high energy endurance issues. The book is intended for a wide audience, such as scientists who are new to the field, practitioners, as well as students in the STEM and STEP fields, as well as students working on batteries. The sections on safety and policy would be of great interest to engineers and technologists who want to obtain a solid grounding in the fundamentals of battery science arising from the interaction of electrochemistry, solid-state materials science, surfaces, and interfaces.
| Author | : Ziying Wang |
| Publisher | : |
| Total Pages | : 152 |
| Release | : 2016 |
| Genre | : |
| ISBN | : |
Lithium ion batteries have become one of the most important rechargeable energy storage devices used in our modern society today. As the demand for such devices shift from portable electronics to electric vehicles and large scale storage in order to utilize energy sustainably, ever increasing energy densities both in terms of weight and volume are needed. To satisfy this demand, lithium ion batteries utilizing solid state electrolytes show promise of a new paradigm shift in energy storage technologies. The introduction of solid state electrolyte could, in principle, yield many advantages over conventional lithium ion batteries. Foremost, lithium metal can be used as the anode along with a high voltage cathode to boost energy density. Secondly, removal of flammable liquid electrolyte greatly improves the inherent safety of the battery. We focused on using Focused Ion Beam (FIB) nano-fabrication technique to prepare Transmission Electron Microscopy (TEM) samples of all-solid-state batteries produced through physical vapor deposition techniques. The particular full cell chemistry of lithium cobalt oxide (LiCoO2) as cathode, amorphous silicon (a-Si) as anode, and lithium phosphorus oxynitrdie (LiPON) as electrolyte was used for investigations. Through analysis of TEM images and electron energy loss spectroscopy (EELS), important interfacial phenomena were observed at the anode-electrolyte interface and the cathode-electrolyte interface. Overcharging of the anode resulted in accumulation of lithium at the anode-current collector interface and interdiffusion of phosphorus and silicon atoms at the anode-electrolyte interface. Furthermore, we developed a unique methodology using FIB fabrication techniques to prepare electrochemically active TEM samples of all-solid-state nanobatteries that can be galvanostatically charged in the FIB or TEM. This new methodology enabled in situ TEM observations of a previously undiscovered interfacial layer between the LiCoO2 cathode and LiPON electrolyte. This interfacial layer is composed of a highly disordered rocksalt like cobalt oxide phase that is oxidized and forms lithium oxide species during in situ charge. Additionally, electrochemically cycling at elevated temperatures (80 °C) causes further decomposition of the cathode layer decreasing the overall capacity and increasing interfacial impedance of the cell. These results indicate that proper engineering of electrode-electrolyte interface is essential for the performance of all-solid-state batteries.
| Author | : Zewen Zhang |
| Publisher | : |
| Total Pages | : 0 |
| Release | : 2023 |
| Genre | : |
| ISBN | : |
Electrochemical energy technologies, such as batteries, are essential for decarbonizing our economy and enabling clean energy storage for a sustainable future. Underlying the battery technology are multiple coupled dynamic processes that span many length scales including electron transport, ionic diffusion, ion solvation/desolvation, surface adsorption, interfacial evolution and interphase formation, intermediate states, and phase/chemical transformations. The advancement in scientific understanding and technological innovations for batteries entail an atomic- and molecular-resolution understanding of the key materials and fundamental processes governing the operation and failure of the systems. However, these key components are often highly sensitive and remain difficult to resolve with conventional interrogation methods. The rapid progress in cryogenic electron microscopy (cryo-EM) for physical sciences starts to offer researchers new tools and methods to probe many otherwise inaccessible length scales and time scales of components and phenomena in electrochemical energy science. Specifically, weakly bonded and reactive materials, interfaces and phases that typically degrade under high energy electron-beam irradiation and environmental exposure can potentially be protected and stabilized by cryogenic methods. Such initial efforts bring up thrilling opportunities to address many crucial yet unanswered questions in electrochemical energy science, which can eventually lead to new scientific discoveries and technological breakthroughs. My PhD dissertation entails the use and the development of cryo-EM methods for batteries to gain functional insights into the critical battery interfaces, which may provide guidance and design principles for practical next-generation lithium battery chemistries. In Chapter 1, I will give an introduction to lithium batteries on the history and current limitations, and motivate the need to resolve the interfaces with high spatial and chemical resolution. In Chapter 2, I will briefly introduce transmission electron microscopy (TEM) and cryo-EM, as well as relevant analytical capabilities for the atomic resolution of structural and chemical characterization of materials. In Chapter 3, I will show how cryo-EM can be used to derive new insights into the cathode electrolyte interphase (CEI), allowing for new engineering principles for cathode interfacial protection. In Chapter 4, I will introduce method advancement in cryo-EM for batteries in which we incorporate liquid electrolytes into the investigation, and used Li metal anode solid-electrolyte interphase (SEI) analysis as an example to show how these studies can be leveraged to refine the SEI model and guide the electrolyte design and engineering for next generation batteries. In Chapter 5, I will talk about how we advance from 2D analysis into 3D, and use cryo-EM tomography (cryo-ET) to resolve nanoscale heterogeneities developed in Li metal anodes in 3D. In Chapter 6, I will conclude the dissertation with broader insights gained from my studies and an outlook for how we could push the boundary of understanding dynamic processes during battery operations to guide the rational design of next generation batteries.
| Author | : Timothy Stephen Plett |
| Publisher | : |
| Total Pages | : 115 |
| Release | : 2017 |
| Genre | : |
| ISBN | : 9780355307702 |
Lithium ion battery technology has flourished since its introduction into the consumer market. Not only has it helped revolutionize consumer electronics, it also compliments R&D into clean forms of energy harvest e.g. solar, wind, and hydro-electric. As demand for the technology grows, innovative approaches have been taken to improve capacity, output, and lifetime in Li-ion batteries. The approach studied in this research involves the inclusion of nanostructures, which have the potential to significantly increase capacity. While several techniques to fabricate nanostructures are understood, underlying phenomena governing ion transport in and around these nanostructures is only partially understood, which could directly impact design principles for such devices.This thesis examines a variety of model systems which could serve to simulate environments found in proposed devices and answer questions regarding ion transport phenomena. The main components we studied from such battery systems were electrolyte and cathode materials. The electrolyte experiences different ion transport phenomena arising from the nanoconfinement of the cathode structures both around and inside the electrode material. Thus, having model systems to examine electrolyte and cathode material separately and in tandem is useful for elucidating phenomena without the challenge of deconvolution resulting from other current-carrying mechanisms.Our main tools for carrying out our research were synthetic nanopores. The nanopore structures afforded means to access nanoscale, control environment, and even fabricate components for study. By studying the current-voltage curves in these systems, we were able to draw meaningful conclusions about mechanisms of ion transport in these model systems. The main findings of this research include the inducement of positive surface charge on nanopore structures by organic solvent-based electrolytes by means of dipole and/or ion adsorption, positive evidence of gel electrolyte fitting current models of ion current rectification, and the impact of oxidation state and cycling in cathode material on ion transport through its porous media. Each of these findings is directly related to the thrust of the research and potentially provide insights for future battery design.
| Author | : Snehashis Choudhury |
| Publisher | : |
| Total Pages | : 239 |
| Release | : 2019 |
| Genre | : Lithium cells |
| ISBN | : 9783030289447 |
This thesis makes significant advances in the design of electrolytes and interfaces in electrochemical cells that utilize reactive metals as anodes. Such cells are of contemporary interest because they offer substantially higher charge storage capacity than state-of-the-art lithium-ion battery technology. Batteries based on metallic anodes are currently considered impractical and unsafe because recharge of the anode causes physical and chemical instabilities that produce dendritic deposition of the metal leading to catastrophic failure via thermal runaway. This thesis utilizes a combination of chemical synthesis, physical & electrochemical analysis, and materials theory to investigate structure, ion transport properties, and electrochemical behaviors of hybrid electrolytes and interfacial phases designed to prevent such instabilities. In particular, it demonstrates that relatively low-modulus electrolytes composed of cross-linked networks of polymer-grafted nanoparticles stabilize electrodeposition of reactive metals by multiple processes, including screening electrode electrolyte interactions at electrochemical interfaces and by regulating ion transport in tortuous nanopores. This discovery is significant because it overturns a longstanding perception in the field of nanoparticle-polymer hybrid electrolytes that only solid electrolytes with mechanical modulus higher than that of the metal electrode are able to stabilize electrodeposition of reactive metals.
| Author | : |
| Publisher | : |
| Total Pages | : 0 |
| Release | : 1993 |
| Genre | : |
| ISBN | : |
In these report we continue to describe the results obtained in the course of the investigation of the electrochemical properties of gel-type polymer electrolytes formed by immobilization of liquid solutions (e.g., solutions of lithium salts in propylene carbonate-ethylene carbonate, PC/EC mixtures) in polymer (e.g., poly(acrylonitrile), PAN) matrices. In particular, we have continued to investigate the characteristics and the properties of the interface with the lithium metal electrode in order to complete task (i) which is focused on the clarification and the understanding of the basic properties of the gel-type, polymer electrolytes (see previous reports).
| Author | : |
| Publisher | : |
| Total Pages | : |
| Release | : 2015 |
| Genre | : |
| ISBN | : |
