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A closer look at ion transport / editor, Jun Mei.

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Format:
Book
Contributor:
Mei, Jun, editor.
Series:
Materials science and technologies series.
Materials Science and Technologies Series
Language:
English
Subjects (All):
Ion acoustic waves.
Physical Description:
1 online resource (0 pages)
Edition:
First edition.
Place of Publication:
New York : Nova Science Publishers, [2025]
Summary:
"Ion transport is a fundamental process that could be intensively identified in various natural phenomena and practical applications. Understanding the basic principles and the underlying mechanisms of ion transport is essential for promoting advancements in science and engineering. This book offers an in-depth exploration of the fundamental and applied aspects of ion transport mechanisms, serving as an essential guide for students, researchers, and professionals in the fields of biomedicine, physics, chemistry, materials science, and energy technologies. This comprehensive book delves into the core principles that govern ion movement in solid, liquid, and hybrid systems, with a strong focus on applications in energy storage devices. It brings forward cutting-edge research on advanced materials, showing how these innovations can significantly enhance energy storage performance. Through a combination of theoretical insights, mathematical modelisation, and practical examples, this book bridges the gap between scientific research and real-world applications. The book also highlights emerging trends in ion transport, including the role of nanomaterials in shaping the future of energy solutions"-- Provided by publisher.
Contents:
Intro
Contents
Preface
Acknowledgments
Chapter 1
Ion Transport: A Brief Overview of Properties and Applications
Abstract
Introduction
Properties of Ion Transport
Ion Selectivity
Diffusion Coefficients
Ionic Mobility
Ionization States
Ion Transport Channels
Electrochemical Potential
Applications of Ion Transport
Biomedical Applications
Energy Storage and Conversion
Environmental Remediation
Sensing and Detection
Materials Science
Conclusion
Disclaimer
References
Chapter 2
Mathematical Modelisation of Ion Transport Across Neuron Membranes, Along Axon, Dendrites, and in Neural Networks
Mathematical Modelisation of Ion Transport Across a Passive Biological Neuron Membrane Using Integer Order Derivatives
Hodgkin-Huxley Mathematical Model of Ion Transport Across Active Membrane of the Squid Giant Axon Using Integer Order Derivatives
Morris-Lecar Model for Ion Transport Across the Membrane of Barnacle Giant Muscle Fiber Using Integer Order Derivatives
Mathematical Modelisation of Ion Transport Across Passive Membrane and Voltage Propagation Along Dendrite and Axon Using Integer Order Derivatives
Mathematical Modelisation of Ion Transport Across Active Membrane and Voltage Propagation Along Dendrite and Axon Using Integer Order Derivatives
Mathematical Modelisation of Ion Transport in a Neural Network Using Integer Order Derivatives
Comment
Mathematical Modelisation of Ion Transport through a Passive Biological Neuron Membrane Using Classic Caputo or classic Riemann-Liouville Temporal Fractional Order Derivatives
Hodgkin-Huxley Type Description of Ion Transport Across the Active Membrane of the Squid Giant Axon Using Classic Caputo or Classic Riemann-Liouville Temporal Fractional Order Derivatives.
Morris-Lecar Type Model for Ion Transport Across the Membrane of the Barnacle Giant Muscle Fiber Using Classic Caputo Fractional Order Derivatives
Mathematical Model for Ion Transport Across Active Membrane and Voltage Propagation Along Dendrite and Axon Using Classic Caputo Temporal Partial Fractional Derivative or Classic Riemann-Liouville Temporal Partial Fractional Derivative
Mathematical Modelisation of Ion Transport in a Neural Network Using Classic Caputo Fractional Derivative
Mathematical Modelisation of Ion Transport through a Passive Biological Neuron Membrane Using General Caputo or General Riemann-Liouville Fractional Order Derivatives
Hodgkin-Huxley Type Model for Ion Transport Across the Membrane of the Squid Giant Axon Using General Caputo or General Riemann-Liouville Fractional Order Derivatives
Other Models
Chapter 3
Mathematical Modelisation of Ion Transport through the Membrane of Cardiac Tissue Cells and Cardiac Tissue
FitzHugh-Nagumo Model of Ion Transport in Cardiac Tissue Using Integer Order Derivatives
Noble Model for Ion Transport in Cardiac Tissue Cells Using Integer Order Derivatives
Beeler-Reuter and Other Type of Models for Ion Transport in Cardiac Tissue Cells Using Integer Order Derivatives
Monodomain Model for Ion Transport in Cardiac Tissue Using Integer Order Derivatives
Bidomain Models for Ion Transport in Cardiac Tissue Using Integer Order Derivatives
Monodomain Models for Ion Transport in Cardiac Tissue Using Classic Caputo or Classic Riemann-Liouville Fractional Order Derivatives
Monodomain Models for Ion Transport in Cardiac Tissue Using General Caputo or General Riemann-Liouville Fractional Order Derivatives
References.
Chapter 4
Ion Diffusion and Transport in Li-Ion Batteries
Diffusion Theory
Basic Characteristics of Diffusion
Diffusion Equations
Fick's First Law
Fick's Second Law (Diffusion Kinetic Equation)
Factors Affecting Diffusion
Basic Working Principles of Li-Ion Batteries
Examples of Li Ion Diffusion in DFT Calculations
Chapter 5
MXene-Based Materials for Zinc Ion Transport in Batteries
Working Principles of ZIBs
Structural Modifications on MXenes
Doping
Intercalation
Defect Engineering
Heterogeneous Interface
Oxidation and Selenization
MXenes-Based Electrodes
MXenes/TMOs Composites
MXenes/TMDs Composites
MXenes/Polymer Composites
MXenes/Carbonaceous Composites
Others
Chapter 6
Counter-Ion Transport Selectivity of Ion Exchange Membranes: Electrodialysis and Ionic Conductivity
Transport of Counter-Ions through Ion Exchange Membranes in ED
Theory of Ion Transport through Ion Exchange Membranes
Limiting Current Density
Counter-Ion Transport Selectivity in ED
Membrane Counter-Ion Transport Selectivity Evaluated via the Ionic Conductivity Approach
Solution - Diffusion Transport Model
Correlation between Membrane Ionic Conductivity and Selectivity
The Counter-Ion Mobility Ratio Incorporating Manning's Counter-Ion Condensation
The Dependence of Membrane Counter-Ion Mobility on Its Composition
The Impact of Donnan Electrolytes
Chapter 7
Two-Dimensional Materials for Zinc-Air Batteries
Working Mechanisms of ZABs
2D Materials for Air Electrode
2D Metallic Materials
2D Non-Metallic Materials.
Combination of 2D Metallic and 2D Non-Metallic Materials
2D Materials for Zinc Anode
2D Materials for Separator and Electrolyte
About the Editor
List of Contributors
Index
Blank Page.
Notes:
Includes bibliographical references and index.
Description based on publisher supplied metadata and other sources.
Description based on print version record.
Other Format:
Print version: Mei, Jun A Closer Look at Ion Transport
ISBN:
9798895305331

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