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VOLUME 1 <br> PART 1: FUNDAMENTALS <br> The Need for Stationary Energy Storage <br> History of Flow Batteries <br> General Electrochemical Fundamentals of Batteries General Aspects and Fundamentals of Flow Batteries <br> Redox-mediated Processes <br> Membranes for Flow Batteries <br> Standards for Flow Batteries <br> Safety Considerations of the Vanadium Flow Battery <br> A Student Workshop in Sustainable Energy Technology: The Principles and Practice of a Rechargeable Flow Battery <br> <br> PART 2: CHARACTERIZATION OF FLOW BATTERIES AND MATERIALS <br> Characterization Methods in Flow Batteries: A General Overview <br> Electrochemical Methods <br> Radiography and Tomography <br> Characterization of Carbon Materials <br> Characterization of Membranes for Flow Batteries <br> <br> PART 3: MODELING AND SIMULATION <br> Quantum Mechanical Modeling of Flow Battery Materials <br> Mesoscale Modeling and Simulation for Flow Batteries <br> Continuum Modelling and Simulation of Flow Batteries <br> Pore-scale Modeling of Flow Batteries <br> Dynamic Modelling of Vanadium Flow Batteries for System Monitoring and Control <br> Techno-economic Modelling and Evaluation of Flow Batteries <br> Machine Learning for FB Electrolyte Screening <br> <br> VOLUME 2 <br> PART 4: VANADIUM FLOW BATTERIES <br> The History of the UNSW All‐Vanadium Flow Battery Development <br> Vanadium Electrolytes and Related Electrochemical Reactions <br> Electrodes for Vanadium Flow Batteries (VFBs) <br> Membranes for Vanadium Flow Batteries <br> Advanced Flowfield Architecture for Vanadium Flow Batteries <br> State‐of‐Charge Monitoring for Vanadium Redox Flow Batteries <br> Rebalancing/Regeneration of Vanadium Flow Batteries <br> Life Cycle Analysis of Vanadium Flow Batteries <br> Next‐Generation Vanadium Flow Batteries <br> Asymmetric Vanadium‐based Aqueous Flow Batteries <br> <br> PART 5: OTHER IMPORTANT INORGANIC FLOW BATTERY TECHNOLOGIES <br> Zn/Br Battery - Early Research and Development <br> An Overview of the Polysulfide/Bromine Flow Battery <br> Fe/Fe Flow Battery <br> Zinc-Cerium and Related Cerium‐Based Flow Batteries: Progress and Challenges <br> Undivided Copper-Lead Dioxide Flow Battery Based on Soluble Copper and Lead in Aqueous <br> All‐copper Flow Batteries <br> Hydrogen‐Based Flow Batteries <br> <br> VOLUME 3 <br> PART 6: ORGANIC FLOW BATTERIES <br> Aqueous Organic Flow Batteries <br> Metal Coordination Complexes for Flow Batteries <br> Organic Redox Flow Batteries: Lithium‐Ion‐based FBs <br> Nonaqueous Metal‐Free Flow Batteries <br> Polymeric Flow Batteries <br> <br> PART 7: INDUSTRIAL AND COMMERCIALIZATION ASPECTS OF FLOW BATTERIES <br> Inverter Interfacing and Grid Behaviour <br> Flow‐Battery System Topologies and Grid Connection <br> Vanadium FBESs installed by Sumitomo Electric Industries, Ltd <br> Industrial Applications of Flow Batteries <br> Applications of VFB in Rongke Power <br> Metal‐Free Flow Batteries Based on TEMPO <br> Commercialization of All‐Iron Redox Flow‐Battery Systems <br> Application of Hydrogen-Bromine Flow Batteries: Technical Paper <br> Some Notes on Zinc/Bromine Flow Batteries <br> Mobile Applications of the ZBB <br>

<p><i><b>Christina Roth</b> is Full Professor at the University of Bayreuth (Germany), where she is the Chair of Electrochemical Process Engineering. </i> <p><i><b>Jens Noack</b> is Adjunct Associate Professor at the University of New South Wales in Sydney (Australia) and works at the German Fraunhofer Institute for Chemical Technology in the Department of Applied Electrochemistry. </i> <p><i><b>Maria Skyllas-Kazacos</b> is Professor Emeritus in the School of Chemical Engineering at the University of New South Wales in Sydney (Australia), where she has been a member of the academic staff since 1980.</i>

<p><b>The premier reference on flow battery technology for large-scale, high-performance, and sustainable energy storage</b> <p>From basics to commercial applications, <i>Flow Batteries</i> covers the main aspects and recent developments of (Redox) Flow Batteries, from the electrochemical fundamentals and the materials used to their characterization and technical application. Edited by a team of leading experts, including the “founding mother of vanadium flow battery technology” Maria Skyllas-Kazacos, the full scope of this revolutionary technology is detailed, including chemistries other than vanadium and organic flow batteries. Other key topics covered in <i>Flow Batteries</i> include: <ul><li> Flow battery computational modeling and simulation, including quantum mechanical considerations, cell, stack, and system modeling, techno-economics, and grid behavior</li> <li> A comparison of the standard vanadium flow battery variant with new and emerging flow batteries using different chemistries and how they will change the field</li> <li> Commercially available flow batteries from different manufacturers, their technology, and application ranges</li> <li> The pivotal role of flow batteries in overcoming the global energy crisis</li></ul> <p><i>Flow Batteries</i> is an invaluable resource for researchers and engineers in academia and industry who want to understand and work with this exciting new technology and explore the full range of its current and future applications.

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