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This volume considers various methods of energy storage that make use of electrochemical reactions, electric and magnetic fields, and chemical reactions. This book begins with a consideration of the use of batteries as a means of storing electrical energy. Various common battery chemistries are presented along with a summary of common battery sizes. The electrochemistry of a lithium-ion (Li-ion) cell is discussed in detail. Sodium-based batteries are discussed, as are vanadium flow batteries. The applications of batteries for energy storage are overviewed, concentrating on transportation technologies and grid-scale storage. Methods for storing energy in the form of electric fields include the use of supercapacitors and superconducting coils. The design of capacitors, including supercapacitors, pseudocapacitors, and hybrid capacitors is presented. The applications of supercapacitors for high-power, short-term energy storage are discussed. The use of superconducting magnets to store large amounts of electrical energy without resistive loss is presented. The application of superconducting electrical storage for grid stability is considered. Final chemical energy storage techniques are considered. The use of hydrogen as an energy carrier is discussed in detail. The concept of a future hydrogen economy has been popular in recent years. This volume considers the efficiency of such an approach. Other chemical energy carriers, such as methane, methanol, and ammonia, are discussed.
List of contents
Preface.- Batteries.- Supercapacitors and Superconductors.- Chemical Energy Storage Methods.- Bibliography.- Author's Biography .
About the author
Richard A. Dunlap received a B.S. in Physics from Worcester Polytechnic Institute in 1974, an A.M. in Physics from Dartmouth College in1976 and a Ph.D. in Physics from Clark University in 1981. Since receiving his Ph.D. he has been on the Faculty in the Department of Physics and Atmospheric Science at Dalhousie University where he currently holds an appointment as Research Professor. Prof. Dunlap has published more than 300 refereed research papers and his research interests have included, magnetic materials, amorphous alloys, critical phenomena, hydrogen storage, quasicrystals, superconductivity and materials for advanced batteries. He is the author of seven previous books: Experimental Physics: Modern Methods (Oxford, 1988); The Golden Ratio and Fibonacci Numbers (World Scientific, 1997); An Introduction to the Physics of Nuclei and Particles (Brooks/Cole, 2004); Sustainable Energy (Cengage, 1st ed. 2015, 2nd ed. 2019); Novel Microstructures for Solids (Morgan & Claypool, 2018; Particle Physics (Morgan & Claypool 2018); and The Mossbauer Effect (Morgan & Claypool, 2019).
