Towards Next Generation Energy Storage Technologies
From Fundamentals to Commercial Applications
1. Edition October 2024
480 Pages, Hardcover
117 Pictures (116 Colored Figures)
4 tables
Handbook/Reference Book
Short Description
summarizes the fundamental energy storage mechanisms, critical achievements, and critical challenges from the view of practical application.
Develop the clean technologies of the future with these novel energy storage technologies
Energy storage is a crucial component of the broader battle to develop clean energy sources and transform the power grid in light of advancing climate change. Numerous new energy storage technologies based on electrochemical redox reactions have recently been developed or proposed, promising to reduce costs and enable energy-dense devices and applications of many kinds. This urgent work demands to be incorporated into chemistry, materials science, and industry at every level.
Towards Next Generation Energy Storage Technologies offers a comprehensive overview of these novel technologies and their applications. Beginning with an introduction to the fundamentals of electrochemistry and energy storage, it offers current and future research questions, design strategies, and much more. It is a must-own for scientists and engineers looking to develop the energy grid of the future.
Towards Next Generation Energy Storage Technologies readers will also find:
* Summaries of state-of-the-art research and open challenges
* Detailed discussion of technologies including lithium-ion batteries, all-solid-state batteries, aqueous multi-valence energy storage systems, and more
* Discussion of applications including electric vehicles, aerospace devices, and many others
Towards Next Generation Energy Storage Technologies is ideal for materials scientists, inorganic chemists, electrochemists, electronics engineers, and anyone working on the clean energy grid or electrical devices.
FUNDAMENTALS OF ELECTROCHEMICAL ENERGY STORAGE TECHNOLOGIES
Typical Battery Pattern and Corresponding Functions
Operating Mechanism of the Devices
Critical Parameters and Design Proposal
Common Investigation Technologies
Common Design Strategies for High-Performance Electrode Materials
LITHIUM-ION BATTERIES
Brief Introduction
Cathode Materials
Anode Materials
SODIUM-ION BATTERIES
Introduction
Energy Storage Mechanism
Cathode Materials
Anode Materials
Electrolyte
Sodium-Ion Battery in Extreme Temperature
Other Na Based Technologies
Summary and Outlook
ALL-SOLID-STATE BATTERIES
Introduction
Ion Transport Mechanism
Key Performance Parameters
Classification of Solid Electrolytes
Practical Problems and Critical Challenges
Practical Advances in Electric Vehicles and other Areas
LITHIUM-SULFUR BATTERY
Fundamental Understanding of Li-S Battery
Sulfur Cathode
Electrolyte
Anode
Li-S Pouch Cells Analysis
AQUEOUS MULTIVALENT METAL ION BATTERIES: FUNDAMENTAL MECHANISM AND APPLICATION
Introduction
Classification Based on Energy Storage Mechanism
Highly Stable and Energetic Cathodes
Strategies for Dendrite-Free Metal Anodes
Strategies for Design Electrolyte
Design Strategies for Extreme Temperatures
Practical Progress in Grid-Scale Energy Storage and Wearable Device
LI-O2 AND LI-CO2 BATTERIES
Introduction
The Mechanism for Li-O2 and Li-CO2 Batteries
Cathode Materials Design Strategy
Electrolyte and Electrolyte Stability
Stable Anode/Electrolyte Interface Construction
Application Potential Analysis
SUPERCAPACITORS
Brief Introduction
Energy Storage Mechanism
Electrode Materials
Electrolyte
Conclusion
BATTERY-SUPERCAPACITOR HYBRID DEVICES
Introduction
Classification Based on Energy Storage Mechanism
Key Scientific Problems
Electrode Materials
Microgrids Energy Storage
Summary and Perspectives
FUEL CELLS
Overview
Thermodynamics and the Kinetics
Proton Exchange Membrane Fuel Cell
Alkaline Fuel Cells
Other Fuel Cells
Fuel Cell System