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Electrophoresis
This book describes a description of electrophoresis-a method that separates charged particles in a fluid influenced by an electric field. It elaborates on the principles behind this method and various applications. Innovations are also given an account to provide insight into how this method can be used for practical applications such as the application of electrophoresis in biochemistry, molecular biology, and analytical chemistry. This book covers electrophoresis in different methods, such as classic and modern types, from development to its future application. The reader of the book can acquire practical information on electrophoresis, with more and more application in scientific studies today.
Author(s): Oana-Maria Boldura
NA Pages 
Physics of Electrochemical Processes
This book makes a deep dive into the physical principles underlying electrochemical processes, mainly focusing on the electrical double layer (EDL), solute transport, and electrokinetics. In this text, there is coverage of models that describe the EDL, such as the Gouy-Chapman-Stern model, and extends into more complex phenomena such as combined mass transport and chemical reactions, reverse osmosis, and electrodialysis. It also goes into the physics of electrochemical systems at the microscopic level, both non-Faradaic and Faradaic processes. The book applies to fields like bioelectrochemistry and environmental chemistry and even briefly discusses some experimental methods and numerical modeling used in electrochemical research.
Author(s): P.M. Biesheuvel, J.E. Dykstra
513 Pages
This textbook discusses the electrochemistry of solids with particular emphasis on the properties of solid materials in electrochemical systems. It deals with basic aspects of solid-state reactions, assembly and geometry of solid oxide fuel cells, polymer electrolyte membrane fuel cells, and batteries, with emphasis on the reactivity and kinetic properties of solid materials such as sintering, creep, and demixing. Its advanced applications involve the understanding of electrolysis cells, solid-state processes as components of energy conversion, and storage technologies in relation to the efficiency and potential impact. To this end, the researcher or student with material should work with individuals demonstrating a propensity for materials but may not have expressed specific interests regarding their electrochemical characteristics or the opportunity of putting such properties toward potential work in energy systems. Accordingly, the book considers the perspectives of both theory and practical application.
Author(s): Truls Norby, Ola Nilsen
84 Pages
Understanding Magnesium Ion Electrochemistry
This thesis examines the electrochemistry of magnesiumion systems by modifying the Lewis acidbase pair to improve the stability and performance of magnesium electrolytes. It specifically focuses on two novel approaches aimed at improving non-Grignard magnesium electrolytes oxidative stability and reducing corrosion in stainless steel systems. The work discusses the surface modification of carbon electrodes and the use of molybdenum-oxo complexes for proton reduction. It concludes in discussions toward future prospects in magnesium-ion electrochemistry, especially for high-performance energy storage systems.
Author(s): Emily G. Nelson, University of Michigan
115 Pages
Electrochemical Energy Engineering
This is an online resource which explores basic electrochemical concepts regarding energy engineering. The text spans from principles in electric charge and potential to thermodynamics, as well as the role of electrode reactions. It elaborates on the theory behind electroactive layers and modified electrodes, alongside governing electrochemical response principles. Scanning probe methods, photoelectrochemistry, and spectroelectrochemistry techniques are covered. This note grounds the reader in electrochemical principles with a focus on the application of these principles in energy systems, making it very useful for students and engineers interested in electrochemical energy conversion and storage technologies.
Author(s): Prof. Sung, Yung Eun
NA Pages