Chemical sensor technology

This volume is the fourth in a series of annual reviews on progress in the research and technology, both basic and applied, of chemical sensors. New principles, new devices, and the detailed mechanism of various chemical sensors are described. Chemical sensors continue to grow rapidly in importance encompassing a broad spectrum of technologies covering safety, pollution, fuel economy, medical engineering and industrial processes. More than half the papers in this volume are relevant to biosensing, a strategic field for medical and health care equipment, especially in geriatric medicine. Frequent health checks at home will be increasingly necessary as the proportion of the aged in the population steadily grows. In some cases health conditions will have to be monitored constantly to give warnings or provide emergency assistance at the right time. Because biochemical substances play major roles in physiological processes such as metabolism, excitation and contraction of skeletal muscle and neurotransmission, chemical sensing of the related biochemical substances will eventually become indispensable. Each chapter is written by an expert active in the front lines of chemical sensor research. Not only is the technological essence of the subject provided, but also the background and philosophy, an evaluation of achievements to date and problems to be dealt with. Each topic is described in sufficient depth to be useful to researchers worldwide.

Development of the TGS Gas Sensor (A. Chiba). Invention of the Gas Sensor. Establishment of Figaro Engineering Inc. Some Basic Aspects of Semiconductor Gas Sensors (N. Yamazoe and N. Miura). Microstructure of SnO2 Particles. Influence of Microstructure on Gas Sensitivity. Modifications of SnO2 Surface. Concluding Remarks. Silicon Technologies for Sensor Fabrication (W. Mokwa). Basic Processing Steps. Silicon on Insulator Technology. Silicon Micromechanics. Thin Film Chemical Sensors on Silicon Substrates. Chemical Sensors Based on Silicon Devices. Micromachined Chemical Sensors. Conclusion. Characterization of Oxygen Adsorbates on Semiconductive Oxides (M. Iwamoto). Oxygen Species Adsorbed on Oxides. Adsorption States of Oxygen Species on Oxides. Reactivity of Oxygen Species Adsorbed on Metal Oxides. Conclusions. Miniaturization of Catalytic Combustion Sensors (H. Futata). Conventional Catalytic Combustion Sensors. Improvement for Selective CO Detection. Development of Low-power Sensors. Conclusion. Solid Electrolyte Potentiometric Oxygen Gas Sensors (C.M. Mari and G.B. Barbi). Operating Principles. Precision of Oxygen Partial Pressure Determination. Accuracy and Reliability. Response Time. Materials. Conclusions. NASICON: a Sensitive Membrane for Ion Analysis (P. Fabry and E. Siebert). Structure and Properties of NASICON. NASICON Preparation Processes. ISE Improvements with NASICON. Conclusion. Characterization of Poly(dimethyldiallylammonium chloride) and its Application to Electrochemical Sensors (R.S. Tieman, K.L. Rauen, W.R. Heineman and E.W. Huber). NMR Studies of Irradiated DMDAAC. Electrochemistry of Poly(DMDAAC) Networks on Platinum and Graphite. Solid-state Electrochemical Measurements Using Poly(DMDAAC). Humidity Sensor. Conclusions. Biosensors with Microvolume Reaction Chambers (L. Bousse, J.C. Owicki and J.W. Parce). LAPS Devices. Kinetics of pH Change in Microvolumes. Application to Enzyme-linked Immunoassays. The Measurement of the Metabolism of Living Cells. Conclusion. Enzyme Sensor Utilizing an Immobilized Mediator (F. Mizutani and S. Yabuki). The Use of Conducting Support. The Use of Water-soluble Macromolecular Mediators. Future Prospects. Piezoelectric Biosensors (G.J. Bastiaans). Principles of Piezoelectric Acoustic Sensors. Bioactive Surfaces. Experimental Piezoelectric Biosensors. Future Trends. Sensitization of Dielectric Surfaces by Chemical Grafting Application to ISFETs and ENFETs (P. Clechet, N.J. Renault and C. Martelet). Chemical Sensitization of ISFETs. Surface Silanization of Silica Thin Layer. Conclusion. High Sensitive Immunosensor Employing Surface Photovoltage Technique (T. Katsube and H. Uchida). Surface Photovoltage (SPV) Technique. Experimental Details. Experimental Results. Discussion. Conclusion. Non-invasive Monitoring of Glucose in Blood (J. Kimura, T. Kuriyama, M. Kikuchi and T. Arai). Suction Effusion Fluid as a Bio-chemical Constituent Sensing Sample. ISFET Biosensor for Body Fluid. Feasibility Study by Animal Experiments. SEF Technology Applied to Humans. Conclusion. Biosensing System for Odor Compounds Using Plants (H. Matsuoka). Biosensor and Biosensing. Strategy for the Development of an Odor-sensing System Using Plants. Response Properties of Plant Leaf to CO2 Gas. Mechanism and Significance of Leaf Responsiveness to High Concentrations of CO2 Gas. Responsive Properties of Plant Leaf to Odor Compounds. Quantitative Experiments on Odor Compounds. Concluding Remarks. Index.

The present volume is the third in a series of annual reviews reporting the latest progress being made in research and technology, both basic and applied, in the area of chemical sensors. Chemical sensors continue to grow rapidly in importance encompassing a broad spectrum of technologies covering safety, pollution, fuel economy, medical engineering and industrial processes. Various types of chemical sensors have been devised for detection and monitoring of chemical substances in gases, solutions and organisms, and much work is being done to produce sensitive, selective, reliable and inexpensive sensors. The series aims at contributing to the progress of research and development of chemical sensors. Contributors to the individual volumes are carefully selected by an international editorial board. Each article, written by an expert active in the front lines of chemical sensor research, describes a specific topic. Not only the academic or technological essence of the subject is provided, but also the background and philosophy, evaluation and achievements and future problems. In this way, each topic is described in sufficient depth so as to be useful and stimulating to researchers worldwide.

Gas-Sensing Characteristics of Oxide Whiskers (M. Egashira and Y. Shimizu). Tin Dioxide Gas Sensor - A New Approach to Odor Sensing (T. Nakahara and H. Koda). Theory and Practice of Dielectric-Supported Thin Film Chemiresistors (E.S. Kolesar, Jr.). Multicomponent Analysis in Chemical Sensing (U. Weimar, S. Vaihinger, K.D. Schierbaum and W. Gopel). Automotive Oxygen Sensors (E.M. Logothetis). Principles and Fabrication Materials of Electrochemical Sensors (T.C. Tan and C.C. Liu). Use of High Temperature Proton Conductor for Gas Sensors (H. Iwahara). Development of an SO 2 Sensor Based on Metal Sulfates (G. Adachi and N. Imanaka). Polymer-Based Capacitive Hygrometers (H. Grange and G. Delapierre). Development and Applications of Fiber Optic Sensors (S.M. Angel, T.J. Kulp, M.L. Myrick and K.C. Langry). In-site Fiber Optic Sensing Technique for Chemical Composition and Temperature of Gas at Elevated Temperatures by Infrared Spectroscopy (M. Maeda). The Development and Scope of Ion-Selective Electrodes (J.D.R. Thomas). Microstructured ISFETs (N.F. de Rooij and H.H. van den Vlekkert). Interfacial Electrochemistry of Flavoenzymes and Its Potential Application to the Preparation of a New Enzyme Sensor (I. Taniguchi, H. Eguchi and S. Tomimura). Microvoltammetry and Brain Dialysis (J.B. Justice, Jr. and L.H. Parsons). Ultramicroelectrodes as Sensing Devices for Biological Molecules (T. Matsue and I. Uchida). Recent Development of Immunochemical Sensors and Immunological Assays Using Monoclonal Antibodies Against Small Molecules (T. Uda). Index.

The subjects chosen for this second volume have been carefully selected by the international editorial board to cover new, important progress in this fast-developing field. With contributions from many prominent researchers working at the frontiers of the chemical sensor field, the book provides up-to-date information and inspiration to all readers.

Palladium Gate Hydrogen Sensors (I. Lundstrom). Properties of Pd-Gate Heterostructure Diodes for Hydrogen Detection (Zheng Li and S.J. Fonash). Fabrication of Integrated Thin Film Semiconductor Gas Sensors (A. Grisel and V. Demarne). Ozone Detection by In 2 O 3 Thin Film Gas Sensor (T. Takada). Stability of the Sensitivity of SnO 2 -Based Elements in the Field (Y. Nakamura). Air/Fuel Ratio Sensors Using Perovskite-Type Oxides (H. Arai and Y. Shimizu). Electropolymerized Films as Chemical Sensor Materials (N. Oyama). Design of Polymer Electrolytes-Based Humidity Sensors (Y. Sakai). Humidity Sensor Using TiO 2 -SnO 2 Ceramics (T. Yamamoto and K. Murakami). Electrode Reactions in Potentiometric Gas Sensors (M. Kleitz and E. Seibert). Development of ISFET Using Glassy Solid Electrolytes (Yu.G. Vlasov and Yu. A. Tarantov). Integrated Multibiosensors Fabricated on SOS Chip (T. Kuriyama and J. Kimura). Enzyme Embodies Electrode. A New Amperometric Biosensing Device (S. Yamauchi et al.). Optical Immunosensors (M. Aizawa et al.). The Molecular Recognitive Component of Chemical Sensor Selectivity (M. Thompson et al.). Use of Bacterial Magnetite for Biosensing (N. Nakamura and T. Matsunaga). Biosensing Using Calorimetric Devices (I. Satoh). Index.

Chemical Sensor Technology is a series of annual reviews reporting the latest progress being made in research and technology, both basic and applied, regarding chemical sensors. Chemical sensors continue to grow rapidly in importance encompassing a broad spectrum of technologies covering safety, pollution, fuel economy, medical engineering and industrial processes. Various types of chemical sensors have been devised for detection and monitoring of chemical substances in gases, solutions and organisms, and much work is being done to produce sensitive, selective, reliable and inexpensive sensors. The series aims at contributing to the progress of research and development of chemical sensors. Contributors to the individual volumes are carefully selected by an international editorial board who ensure that as many innovative studies as possible are included. Each article describes a specific topic and is the original work of an expert working in the front lines of chemical sensor research. Contributors are encouraged to describe not only the academic or technological essence of the subject, but also the background and philosophy, evaluation and achievements and future problems. In this way, each topic is described in sufficient depth so as to be useful and stimulating to readers.

Chemical Sensors - Current State and Future Outlook (T. Seiyama). Physical and Chemical Aspects of Oxidic Semiconductor Gas Sensors (G. Heiland, D. Kohl). Tin Dioxide Sensors - Development and Applications (K. Takahata). Development and Application of Ceramic Humidity Sensors (T. Nitta). Limiting Current Type Oxygen Sensors (T. Takeuchi, I. Igarashi). Solid-Electrolyte Sensors for SO 2 and/or SO 3 (W.L. Worrell). Use of Zirconia Sensors in the Metallurgical Industry in Japan (K.S. Goto, M. Susa). Development of a Solid-State Gas Sensor Using Proton Conductor Operative at Room Temperature (N. Miura, N. Yamazoe). Ion Sensors for Microsampling (Y. Umezawa, M. Sugawara). Suspended Gate Field Effect Transistor (M. Josowicz, J. Janata). Micromachining for Chemical Sensors (S. Shoji, M. Esashi). Micro-Fabrication of Biosensors (I. Karube, H. Suzuki, E. Tamiya). Medical Applications of the Glucose Sensor (M. Shichiri, R. Kawamori, Y. Yamasaki, N. Ueda). Design and Applications of Biosensors in Medicine: Study on Artificial Pancreas (M. Mascini, G. Palleschi, D. Moscone). Optical Chemical Sensor (K. Nishizawa). Index.