Overview

Electrochemical methods of chemical analysis have been widely used for many years, most especially the trusty pH electrode and conductivity meter, but also in the mass-manufactured glucose test strips which place electrochemical measurements into the hands of non-scientists. The purpose of this volume is to address advances that will enable new measurement strategies in the future. Surveying research and development advances based on new methods, materials and devices that achieve improved electroanalytical performances, this collection encompasses chip-based systems, through nanodomain approaches and soft interfaces. This book is a vital resource for graduate students and professional analytical chemists.

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9781849738316

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It is a fantastic time to be an electrochemist! Many of the challenges that scientists have to tackle in today's society involve, in one way or another, charge transfer across an interface. These challenges cover the fields of energy, water deionization, electronic manufacturing, material synthesis, or, as in the topic of this book, sensors. The need for simpler, faster, better, and cheaper detection methods is valid for many research disciplines, as well as for manufacturing industries and human activities such as health and environmental monitoring. Electrochemical Strategies in Detection Science is the sixth volume of a Royal Society of Chemistry series dedicated to the advances of the field of Detection Science. This particular item is focused on the most recent updates in electrochemical detection methods. The volume gathers ten chapters, which can be divided into three groups. Three of these chapters focus on the detection of specific targets such as heavy metals (Chapter 1), nanoparticles (Chapter 5), and ions (Chapter 9). Four chapters are oriented towards the fabrication and the applications of electroanalytical systems: microelectrode arrays for biomedical applications (Chapter 2); microchip electrophoresis (Chapter 3); scanning electrochemical microscopy for life science applications (Chapter 4); and nanoelectrodes (Chapter 6). Finally, the three remaining chapters review the state of the art of materials for electrochemical detection: carbon electrodes (Chapter 7); dispersible electrodes (Chapter 8); and ionic liquid-based electrodes (Chapter 10). In approximately 40 pages, each of the chapters presents the basic concepts necessary to understand the fundamentals of the topic before reviewing the most exciting and recent achievements published in the literature. This selection of chapters is a mix between well-established electroanalytical detection methods-e.g., stripping analysis of heavy metals (Chapter 1) and electroanalysis at carbon nanomaterials such as carbon nanotubes and graphene (Chapter 7)-and rather novel research themes such as the electrochemical detection of nanoparticles (Chapter 6) and the concept of dispersible electrodes (Chapter 8). Most of the chapters of Electrochemical Strategies in Detection Science are of an excellent standard, written by leading researchers in the field. This volume offers a comprehensive snapshot of the current state of the art of electrochemical detection methods. Its tutorial tone will enlighten both specialist and non-specialist readerships eager to discover the field and will contribute to guaranteeing a long shelf life. The variety of electrochemical strategies put forward highlights the vital role of electrochemistry in analytical sciences today. -- Gregoire Herzog * Chromatographia * This volume offers a comprehensive snapshot of the current state of the art of electrochemical detection methods. Its tutorial tone will enlighten both specialist and non-specialist readerships eager to discover the field and will contribute to guaranteeing a long shelf life. -- Gregoire Herzog * Chromatographia *

It is a fantastic time to be an electrochemist! Many of the challenges that scientists have to tackle in today's society involve, in one way or another, charge transfer across an interface. These challenges cover the fields of energy, water deionization, electronic manufacturing, material synthesis, or, as in the topic of this book, sensors. The need for simpler, faster, better, and cheaper detection methods is valid for many research disciplines, as well as for manufacturing industries and human activities such as health and environmental monitoring. Electrochemical Strategies in Detection Science is the sixth volume of a Royal Society of Chemistry series dedicated to the advances of the field of Detection Science. This particular item is focused on the most recent updates in electrochemical detection methods. The volume gathers ten chapters, which can be divided into three groups. Three of these chapters focus on the detection of specific targets such as heavy metals (Chapter 1), nanoparticles (Chapter 5), and ions (Chapter 9). Four chapters are oriented towards the fabrication and the applications of electroanalytical systems: microelectrode arrays for biomedical applications (Chapter 2); microchip electrophoresis (Chapter 3); scanning electrochemical microscopy for life science applications (Chapter 4); and nanoelectrodes (Chapter 6). Finally, the three remaining chapters review the state of the art of materials for electrochemical detection: carbon electrodes (Chapter 7); dispersible electrodes (Chapter 8); and ionic liquid-based electrodes (Chapter 10). In approximately 40 pages, each of the chapters presents the basic concepts necessary to understand the fundamentals of the topic before reviewing the most exciting and recent achievements published in the literature. This selection of chapters is a mix between well-established electroanalytical detection methods-e.g., stripping analysis of heavy metals (Chapter 1) and electroanalysis at carbon nanomaterials such as carbon nanotubes and graphene (Chapter 7)-and rather novel research themes such as the electrochemical detection of nanoparticles (Chapter 6) and the concept of dispersible electrodes (Chapter 8). Most of the chapters of Electrochemical Strategies in Detection Science are of an excellent standard, written by leading researchers in the field. This volume offers a comprehensive snapshot of the current state of the art of electrochemical detection methods. Its tutorial tone will enlighten both specialist and non-specialist readerships eager to discover the field and will contribute to guaranteeing a long shelf life. The variety of electrochemical strategies put forward highlights the vital role of electrochemistry in analytical sciences today.

This volume offers a comprehensive snapshot of the current state of the art of electrochemical detection methods. Its tutorial tone will enlighten both specialist and non-specialist readerships eager to discover the field and will contribute to guaranteeing a long shelf life. -- Grégoire Herzog * Chromatographia *

This volume offers a comprehensive snapshot of the current state of the art of electrochemical detection methods. Its tutorial tone will enlighten both specialist and non-specialist readerships eager to discover the field and will contribute to guaranteeing a long shelf life. -- Gregoire Herzog * Chromatographia *

Author Information

Dr. Sub Reddy (C.Chem. MRSC) obtained his first class degree in Chemistry from the University of Manchester. He received his Ph.D. in Membrane-based Electrochemical Biosensing from the same University (1996). His post-doctoral research interests have included the development of quartz crystal-based biosensors, operating in the liquid phase (University of Wales, Bangor; 1994-1997) and the development of application-specific odour sensors (UMIST, Manchester; 1997-1998). Dr. Reddy was Senior Lecturer in Applied Analytical Chemistry at the University of Surrey and recently moved to the University of Central Lancashire as Senior Lecturer in Analytical Chemistry. Current research interests include the development of smart, permselective and biocompatible molecular imprinted polymers and membrane materials for the sensor/sample interface and the advancement of smart materials-based electrochemical, quartz crystal and optical sensors for medical, food and environmental applications. He is particularly interested in developing hydrogel-based molecularly imprinted polymers (HydroMIPs) for the determination of protein markers and other biomarkers and construction of biosensors. Professor Compton is a fellow of the Royal Society of Chemistry and Professor of Chemistry at Oxford University. He is also Editor-in-Chief of Electrochemistry Communications, Fellow of the International Society of Electrochemistry. In 2011 Professor Compton was awarded the RSC Sir George Stokes Award. Craig Banks is Professor of Nano and Electrochemical Technology at Manchester Metropolitan University, UK.

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