Batteries
Present and Future Energy Storage Challenges
BARD: ENCY.OF ELECTROCHEMISTRY
1. Edition September 2020
960 Pages, Hardcover
315 Pictures (193 Colored Figures)
Handbook/Reference Book
Short Description
The book provides a clearly written, comprehensive overview of the most relevant battery technologies at present and in the years to come.
Further versions
Part of the Encyclopedia of Electrochemistry, this comprehensive, two-volume handbook offers an up-to-date and in-depth review of the battery technologies in use today. It also includes information on the most likely candidates that hold the potential for further enhanced energy and power densities. It contains contributions from a renowned panel of international experts in the field.
Batteries are extremely commonplace in modern day life. They provide electrochemically stored energy in the form of electricity to automobiles, aircrafts, electronic devices and to smart power grids. Comprehensive in scope, 'Batteries' covers information on well-established battery technologies such as charge-carrier-based lead acid and lithium ion batteries. The contributors also explore current developments on new technologies such as lithium-sulfur and -oxygen, sodium ion, and full organic batteries.
Written for electrochemists, physical chemists, and materials scientists, 'Batteries' is an accessible compendium that offers a thorough review of the most relevant current battery technologies and explores the technology in the years to come.
INTRODUCTION
The Role of Batteries for the Successful Transition to Renewable Energy Sources
Fundamental Principles of Battery Electrochemistry
PRESENTLY EMPLOYED BATTERY TECHNOLOGIES
Lead Acid - Still the Battery Technology with the Largest Sales
Ni/Cd and Ni-MH - the Transition to "Charge Carrier"-Based Batteries
Brief Survey on the Historical Development of Lithium-Ion Batteries
Present Lithium-Ion Battery Chemistries
Anticipated Progress in the Near- to Mid-Term Future of Lithium-Ion Batteries
Safety Considerations with Lithium-Ion Batteries
Recycling of Lithium-Ion Batteries
Vanadium Redox Flow Batteries
Redox Flow - Zn-Br
The Sodium/Nickel Chloride battery
High temperature battery technologies: Na/S
Solid-State Batteries with Polymer Electrolytes
VOLUME 2
POTENTIAL CANDIDATES FOR FUTURE ENERY STORAGE
Solid-State Batteries with Inorganic Electrolytes
Li/S
Lithium-Oxygen Batteries
Nonlithium Aprotic Metal/Oxygen Batteries Using Na, K, Mg, or Ca as Metal Anode
Na-Ion Batteries
Multivalent Charge Carriers
Aqueous Zinc Batteries
Full Organic Batteries
Dominic Bresser is presently establishing a young investigator research group at the Helmholtz Institute Ulm (HIU) and Karlsruhe Institute of Technology (KIT), Germany. The focus of the group?s activities is on the investigation and development of alternative lithium-ion anode materials. Simultaneously, he is working with Prof. Stefano Passerini on aqueous electrode processing technologies for high-energy lithium-ion cathodes and pursuing his habilitation at the University of Ulm. Prior to his present activities, he held a two-years postdoctoral position and Enhanced Eurotalents Fellowship at the CEA in Grenoble, France, where he was studying nanostructured single-ion conductors and poly(ionic liquid)s as electrolyte systems. Beforehand, he carried out his PhD in the group of Stefano Passerini at the University of Muenster, Germany, studying nanostructured active materials for lithium- and sodium-based batteries. He is Co-Author of more than 50 peer-reviewed international publications (h-index of 21) as well as three book chapters and several international patent applications.
Arianna Moretti is a senior scientist at the Helmholtz Institute Ulm (HIU) for Electrochemical Energy Storage, Karlsruhe Institute of Technology (KIT), Germany. Her research activities focus on Li-metal and Li-ion batteries and include the development of electrolytes and electroactive materials, electrode processing, cell aging and post-mortem studies. In 2009, she graduated in Chemistry at the University of Camerino, Italy, with a dissertation on catalysts for proton exchange membrane fuel cells. In 2013, she accomplished her PhD studies working in the electrochemistry group of Prof. Marassi on olivine-type cathode material. Afterward she joined as Post-doc the group of Prof. Passerini at WWU Münster and MEET (Münster Electrochemical Energy Technology) conducting the research on ionic liquids and vanadium oxides. She is co-author of more than 20 peer-reviewed publications with an h-index of 10.
Alberto Varzi is a senior scientist at the Helmholtz Institute Ulm (HIU) for Electrochemical Energy Storage, with a research focus on electrochemical energy storage devices such as lithium-ion, lithium-sulfur batteries and supercapacitors. He studied Chemistry of Materials at the University of Bologna, Italy and graduated in 2008 working with Prof. Mastragostino on catalysts and membranes for direct methanol fuel cells. He continued his education in Germany and received his PhD in 2013 from the University of Ulm, working with Dr. Margret Wohlfahrt-Mehrens on carbon nanotubes for lithium-ion battery applications. Postdoctoral research he did with Prof. Passerini at WWU Münster and MEET (Münster Electrochemical Energy Technology), dealing with the development of environmentally friendly materials for high power devices. He co-authored more than 27 peer-reviewed papers, 2 patents, and received close to 1200 citations, with an h-index of 12 and i-10-index of 15.
