《傳感材料與傳感技術(shù)叢書》中第一個(gè)影印系列MOMENTUM PRESS 的Chemical Sensors : Fundamentals of Sensing Materials & Comprehensive Sensor Technologies(6卷,影印為10冊(cè))2013年出版后,受到了專家學(xué)者的一致好評(píng)。為了滿足廣大讀者進(jìn)一步的教學(xué)和科研需要,本次影印其ChemicalSensors:Simulation and Modeling系列5卷,每卷均分為上下冊(cè))。本書是第3卷Solid-State Devices的下冊(cè)(第3卷6~10章內(nèi)容)。
Ghenadii Korotcenkov, received his Ph.D. in Physics and Technology of Semiconductor Materials and Devices in 1976, and his Habilitate Degree (Dr.Sci.) in Physics and Mathematics of Semiconductors and Dielectrics in 1990. For a long time he was a leader of the scientific Gas Sensor Group and manager of various national and international scientific and engineering projects carried out in the Laboratory of Micro- and Optoelectronics, Technical University of Moldova. Currently, Dr. Korotcenkov is a research professor at the Gwangju Institute of Science and Technology, Republic of Korea.
Specialists from the former Soviet Union know Dr. Korotcenkov's research results in the field of study of Schottky barriers, MOS structures, native oxides, and photoreceivers based on Group IIIH-V compounds very well. His current research interests include materials science and surface science, focused on nanostructured metal oxides and solid-state gas sensor design. Dr. Korotcenkov is the author or editor of 11 books and special issues, 11 invited review papers, 17 book chapters, and more than 190 peer-reviewed articles. He holds 18 patents, and he has presented more than 200 reports at national and international conferences.
Dr. Korotcenkov's research activities have been honored by an Award of the Supreme Council of Science and Advanced Technology of the Republic of Moldova (2004), The Prize of the Presidents of the Ukrainian, Belarus, and Moldovan Academies of Sciences (2003), Senior Research Excellence Awards from the Technical University of Moldova (2001, 2003, 2005), a fellowship from the International Research Exchange Board (1998), and the National Youth Prize of the Republic of Moldova (1980), among others.
PREFACE
ABOUT THE EDITOR
CONTRIBUTORS
6 MODELING AND SIGNAL PROCESSING STRATEGIES FOR MICROACOUSTIC
CHEMICAL SENSORS
1 Sensing Principles of Microacoustic Chemical Sensors
1.1 Introduction
1.2 Microacoustic Chemical Sensors
2 Simulation and Modeling of Acoustic Wave Propagation, Excitation, and Detection
2.1 Analytical Solution to the Undisturbed Wave Propagation Problem
2.2 Analytical Solution to the Wave Excitation and Detection Problem
2.3 Finite-Element Method
2.4 Equivalent-Circuit Models
3 Sensor Steady-State Response
3.1 Perturbation Approaches
3.2 Temperature Effects
4 Sensor Dynamics
4.1 Linear Model
4.2 State-Space Description
5 Sensor Signal Processing
5.1 Suppression of Temperature Effects
5.2 Signal Processing Based on Linear Analytical Model
5.3 Wiener Deconvolution
5.4 Kalman Filter
5.5 Discussion of State-Space-Based Signal Processing
6 Summary
7 Nomenclature
References
7 HIERARCHICAL SIMULATION OF CARBON NANOTUBE ARRAY-BASED CHEMICAL SENSORS WITH ACOUSTIC PICKUP
1 Introduction
2 Simulation Levels of Nanodesign
3 Prototype of Hierarchical Simulation System for Nanodesign
4 Continual Simulation of SAW Propagation in a Layered Medium
5 Structure of Carbon Nanotubes and Adsoption Properties of CNT Arrays
5.1 Atomic Structure of Single- and Multiwalled Nanotubes
5.2 Quantum Mechanical Study of the Adsorption of Simple Gases on Carbon Nanotubes
5.3 Molecular Mechanics of Physical Adsorption of the Individual Molecules on the CNT
6 Simulation of a Carbon Nanotube Array-Based Chemical Sensor with an Acoustic Pickup
6.1 Molecular Dynamics Calculation of the Elastic Moduli of Individual Carbon Nanotubes
6.2 Molecular Dynamics Study of Distribution of Adsorbed Molecules in CNT Array Pores and Calculation of Acoustic Parameters of CNT Arrays
6.3 SAW Phase Velocity Change Due to Molecular Adsorption on CNT Arravs in SAW-Based Chemical Sensors
7 Conclusion
References
8 MICROCANTILEVER-BASED CHEMICAL SENSORS
9 MODELING OF MICROMACHINED THERMOELECTRIC GAS SENSORS
10 MODELING SIMULATION, AND INFORMATION PROCESSING FOR DEVELOPMENT OF A POLYMERIC ELECTRONIC NOSE SYSTEM