Signal-Switchable Electrochemical Systems

Bietet einen Überblick über verschiedene elektrochemisch schaltbare Systeme und modifizierte Elektroden. Entwickelte Elektrodenschnittstellen zusammen mit unterschiedlichen, auf Signale ansprechende Materialien ermöglichen schaltbare Eigenschaften von modifizierten Elektroden.

Auteur

Evgeny Katz, PhD, is Milton Kerker Chaired Professor at the Department of Chemistry and Biomolecular Science, Clarkson University, New York. His scientific interests are in the broad areas of bioelectronics, biosensors, biofuel cells, biomolecular information processing and recently in forensic science.

Résumé
A guide to the biological control over electronic systems that lead the way to wearable electronics and improved drug delivery

In recent years, this area of electrochemical systems has developed rapidly and achieved significant progress. Signal-Switchable Electrochemical Systems offers an overview to the wide-variety of switchable electrochemical systems and modified electrodes. The author?a noted researcher and expert on the topic?summarizes research efforts of many groups in a range of universities and countries. The book explores various types of external signals that are able to modify electrode interfaces, for example electrical potential, magnetic field, light, as well as chemical and biochemical inputs.

Multifunctional properties of the modified interfaces allow their responses to complex combinations of external signals. These are integrated with unconventional biomolecular computing systems logically processing multiple biochemical signals. This approach allows the biological control over electronic systems. The text explores the applications in different areas, including unconventional computing, biofuel cells and signal-triggered molecular release in electrochemical systems. This important guide:

-Provides an overview to the biological control over electronic systems and examines the key applications in biomedicine, electrochemical energy conversion and signal-processing
-Offers an important text written by a highly cited researcher and pioneer in the field
-Contains a summary of research efforts of an international panel of scholars representing various universities and countries
-Presents a groundbreaking book that provides an introduction to this interdisciplinary field

Written for scientists working with electrochemical systems and applications with signal-responsive materials, Signal-Switchable Electrochemical Systems presents an overview of the multidisciplinary field of adaptable signal-controlled electrochemical systems and processes and highlights their key aspects and future perspectives.

Contenu
Preface xi

1 Introduction 1

References 1

2 Magneto?]switchable Electrodes and Electrochemical Systems 5

2.1 Introduction 5

2.2 Lateral Translocation of Magnetic Micro/nanospecies on Electrodes and Electrode Arrays 5

2.3 Vertical Translocation of Magnetic Micro/Nanospecies to and from Electrode Surfaces 11

2.4 Assembling Conducting Nanowires from Magnetic Nanoparticles in the Presence of External Magnetic Field 24

2.5 Vertical Translocation of Magnetic Hydrophobic Nanoparticles to and from Electrode Surfaces 24

2.6 Repositioning and Reorientation of Magnetic Nanowires on Electrode Surfaces 45

2.7 Integration of Magnetic Nanoparticles into Polymer?]Composite Materials 49

2.8 Conclusions and Perspectives 51

2.9 Appendix: Synthesis and Properties of Magnetic Particles and Nanowires 54

References 62

Symbols and Abbreviations 69

3 Modified Electrodes and Electrochemical Systems Switchable by Temperature Changes 71

3.1 Introduction 71

3.2 Thermo?]sensitive Polymers with Coil?]to?]Globule Transition 72

3.3 Electrode Surfaces Modified with Thermo?]sensitive Polymers for Temperature?]controlled Electrochemical and Bioelectrochemical Processes 74

3.4 Electrode Surfaces Modified with Multicomponent Systems Combining Thermo?]sensitive Polymers with pH?], Photoand Potential?]Switchable Elements 79

3.4.1 Temperature?] and pH?]sensitive Modified Electrodes 80

3.4.2 Temperature?] and Photo?]sensitive Modified Electrodes 83

3.4.3 Temperature?]sensitive Modified Electrodes Controlled by Complex Combinations of External Signals 89

3.5 Electrodes Modified with Thermo?]switchable Polymer Films Containing Entrapped Metal Nanoparticles Inverted Temperaturedependent Switching 93

3.6 Conclusions and Perspectives 94

References 96

Symbols and Abbreviations 98

4 Modified Electrodes and Electrochemical Systems Switchable by Light Signals 101

4.1 Introduction 101

4.2 Diarylethene?]based Photoelectrochemical Switches 103

4.3 Phenoxynaphthacenequinone?]based Photoelectrochemical Switches 120

4.4 Azobenzene?]based Photoelectrochemical Switches 125

4.5 Spiropyranmerocyanine?]based Photoelectrochemical Switches 141

4.6 Conclusions and Perspectives 158

References 159

Symbols and Abbreviations 167

5 Modified Electrodes Switchable by Applied Potentials Resulting in Electrochemical Transformations at Functional Interfaces 169

References 175

Symbols and Abbreviations 176

6 Electrochemical Systems Switchable by pH Changes 177

6.1 Introduction 177

6.2 Monolayer Modified Electrodes with Electrochemical and Electrocatalytic Activity Controlled by pH Value 178

6.3 Polymer?]Brush?]Modified Electrodes with Bioelectrocatalytic Activity Controlled by pH Value 179

6.4 pH?]Controlled Electrode Interfaces Coupled with in situ Produced pH Changes Generated by Enzyme Reactions 186

6.5 pH?]Triggered Disassembly of Biomolecular Complexes on Surfaces Resulting in Electrode Activation 188

6.6 pH?]Stimulated Biomolecule Release from Polymer?]Brush Modified Electrodes 190

6.7 Conclusions and Perspectives 196

References 197

Symbols and Abbreviations 201

7 Coupling of Switchable Electrodes and Electrochemical Processes with Biomolecular Computing Systems 203

7.1 Introduction 203

7.1.1 General Introduction to the Area of Enzyme?]based Biocomputing (Logic) Systems 203

7.1.2 General Definitions and Approaches Used in Realization of Enzymebased Logic Systems 205

7.2 Electrochemical Analysis of Output Signals Generated by Enzyme Logic Systems 206

7.2.1 Chronoamperometric Transduction of Chemical Output Signals Produced by Enzyme?]based Logic Systems 207

7.2.2 Potentiometric Transduction of Chemical Output Signals Produced by Enzyme?]based Logic Systems 209 7.2.3 pH?]Measurements as a Tool for Transduction of Chemical Output Signals Produced by Enzyme?]based Logic Sys...