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Conducting polymers are organic polymers which contain conjugation
along the polymer backbone that conduct electricity. Conducting
polymers are promising materials for energy storage applications
because of their fast charge-discharge kinetics, high charge
density, fast redox reaction, low-cost, ease of synthesis, tunable
morphology, high power capability and excellent intrinsic
conductivity compared with inorganic-based materials. Conducting
Polymers-Based Energy Storage Materials surveys recent advances in
conducting polymers and their composites addressing the execution
of these materials as electrodes in electrochemical power sources.
Key Features: Provides an overview on the conducting polymer
material properties, fundamentals and their role in energy storage
applications. Deliberates cutting-edge energy storage technology
based on synthetic metals (conducting polymers) Covers current
applications in next-generation energy storage devices. Explores
the new aspects of conducting polymers with processing, tunable
properties, nanostructures and engineering strategies of conducting
polymers for energy storage. Presents up-to-date coverage of a
large, rapidly growing and complex conducting polymer literature on
all-types electrochemical power sources. This book is an invaluable
guide for students, professors, scientists, and R&D industrial
specialists working in the field of advanced science, nanodevices,
flexible electronics, and energy science.
Nanostructured electrode materials have exhibited unrivaled
electrochemical properties in creating elite supercapacitors.
Morphology Design Paradigm for Supercapacitors presents the latest
advances in the improvement of supercapacitors, a result of the
incorporation of nanomaterials into the design - from
zero-dimensional to three-dimensional, and microporous to
mesoporous. The book includes a comprehensive description of
capacitive practices at the levels of sub-atomic and nanoscales.
These have the ability to enhance device performance for an
extensive assortment of potential applications, including consumer
electronics, wearable gadgets, hybrid electric vehicles, stationary
and industrial frameworks. Key Features: Provides readers with a
clear understanding of the implementation of these materials as
electrodes in electrochemical supercapacitors. Covers recent
material designs and an extensive scope of electrode materials such
as 0D to 3D. Explores recent nanostructured-system material designs
that have been created and tested in supercapacitor configurations.
Considers microporous to mesoporous supercapacitor electrode
materials. Features the impact of nanostructures on the properties
of supercapacitors, including specific capacitance, cycle
stability, and rate capability.
Conducting polymers are organic polymers which contain conjugation
along the polymer backbone that conduct electricity. Conducting
polymers are promising materials for energy storage applications
because of their fast charge-discharge kinetics, high charge
density, fast redox reaction, low-cost, ease of synthesis, tunable
morphology, high power capability and excellent intrinsic
conductivity compared with inorganic-based materials. Conducting
Polymers-Based Energy Storage Materials surveys recent advances in
conducting polymers and their composites addressing the execution
of these materials as electrodes in electrochemical power sources.
Key Features: Provides an overview on the conducting polymer
material properties, fundamentals and their role in energy storage
applications. Deliberates cutting-edge energy storage technology
based on synthetic metals (conducting polymers) Covers current
applications in next-generation energy storage devices. Explores
the new aspects of conducting polymers with processing, tunable
properties, nanostructures and engineering strategies of conducting
polymers for energy storage. Presents up-to-date coverage of a
large, rapidly growing and complex conducting polymer literature on
all-types electrochemical power sources. This book is an invaluable
guide for students, professors, scientists, and R&D industrial
specialists working in the field of advanced science, nanodevices,
flexible electronics, and energy science.
Nanostructured electrode materials have exhibited unrivaled
electrochemical properties in creating elite supercapacitors.
Morphology Design Paradigm for Supercapacitors presents the latest
advances in the improvement of supercapacitors, a result of the
incorporation of nanomaterials into the design - from
zero-dimensional to three-dimensional, and microporous to
mesoporous. The book includes a comprehensive description of
capacitive practices at the levels of sub-atomic and nanoscales.
These have the ability to enhance device performance for an
extensive assortment of potential applications, including consumer
electronics, wearable gadgets, hybrid electric vehicles, stationary
and industrial frameworks. Key Features: Provides readers with a
clear understanding of the implementation of these materials as
electrodes in electrochemical supercapacitors. Covers recent
material designs and an extensive scope of electrode materials such
as 0D to 3D. Explores recent nanostructured-system material designs
that have been created and tested in supercapacitor configurations.
Considers microporous to mesoporous supercapacitor electrode
materials. Features the impact of nanostructures on the properties
of supercapacitors, including specific capacitance, cycle
stability, and rate capability.
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