书籍详情
仿真与建模·第5卷:电化学传感器(下册 影印版)
作者:[摩尔] 科瑞特森科韦(Korotcenkov G.) 编
出版社:哈尔滨工业大学出版社
出版时间:2015-01-01
ISBN:9787560348995
定价:¥60.00
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内容简介
This series,Chemical Sensors:Simulation and Mod.eling,is the perfect complement to Momentum Press's six-volume reference series,Chemical Sensors:Fundamentals of Sensing Materials and Chemical Sensors: Comprehensive Sensor Technologies,which present detailed information about materials,technologies,fabrication,and applications of various devices for chemical sensing.Chemical sensors are integral to the automation of myriad industrial processes and everyday monitoring of such activities as public safety,engine performance,medical therapeutics,and many more.
作者简介
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 III-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.
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 III-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.
目录
PREFACE
ABOUT THE EDITOR
CONTRIBUTORS
PART 3: ELECTROCHEMICAL BIOSENSORS
7 NANOMATERIAL-BASED ELECTROCHEMICAL BIOSENSORS N.Jaffrezic-Renault
1 Introduction
2 Nanomaterials: Fabrication, Chemical and Physical Properties
2.1 Conducting Nanomaterials
2.2 Nonconducting Nanomaterials: Magnetic Nanoparticles
3 Conception and Modeling of Amplification Effect in Nanomaterial-Based Enzyme Sensors
3.1 AuNPs-Based Amperometric Sensors
3.2 CNT-Based Amperometric Sensors
3.3 MNP-Based Amperometric Biosensors
3.4 Potentiometric Sensors
3.5 Conductometric and Impedimetric Biosensors
4 Conception and Modeling of Amplification Effect in Nanomaterial-Based Immunosensors
4.1 AuNP-Based Amperometric Immunosensors
4.2 AuNP-Based Potentiometric Sensors
4.3 Impedimetric Sensors
4.4 Conductometric Sensors
5 Conception and Modeling of Amplification Effect in Nanomaterial-Based DNA Biosensors
5.1 Amperometric Sensors
5.2 Impedimetric Sensors
6 Conclusion
References
8 ION-SENSITIVE FIELD-EFFECT TRANSISTORS WITH NANOSTRUCTURED CHANNELS AND NANOPARTICLE-MODIFIED GATE SURFACES: THEORY,MODELING AND ANALYSIS
V K. Khanna
1 Introduction
2 Structural Configurations of the Nanoscale ISFET
2.1 The Nanoporous Silicon ISFET
2.2 The CNT ISFET
2.3 The Si-NW ISFET
3 Physics of the Si-NW Biosensor
3.1 Basic Principle
3.2 Analogy with the Nanocantilever
3.3 Preliminary Analysis of Micro-ISFET Downscaling to Nano-ISFET
3.4 Single-Gate and Dual-Gate Nanowire Sensors
3.5 Energy-Band Model of the NW Sensor
4 Nair-Alam Model of Si-NW Biosensors
4.1 The Three Regions in the Biosensor
4.2 Computational Approach
4.3 Effect of Nanowire Diameter (d) on Sensitivity at Different Doping Densities, with Air as the Surrounding Medium
4.4 Effect of Nanowire Length (L) on Sensitivity at Different Doping Densities, with Air as the Surrounding Medium
4.5 Effect of the Fluidic Environment
4.6 Overall Model Implications
5 pH Response of Silicon Nanowires in Terms of the Site-Binding and Gouy-Chapman-Stern Models
6 Subthreshold Regime as the Optimal Sensitivity Regime of Nanowire Biosensors
7 Effective Capacitance Model for Apparent Surpassing of the Nernst Limit by Sensitivity of the Dual-Gate NW Sensor
8 Tunnel Field-Effect Transistor Concept
9 Role of Nanoparticles in ISFET Gate Functionalization
……
9 BIOSENSORS: MODELING AND SIMULATION OF DIFFUSION-LIMITED PROCESSES
INDEX
ABOUT THE EDITOR
CONTRIBUTORS
PART 3: ELECTROCHEMICAL BIOSENSORS
7 NANOMATERIAL-BASED ELECTROCHEMICAL BIOSENSORS N.Jaffrezic-Renault
1 Introduction
2 Nanomaterials: Fabrication, Chemical and Physical Properties
2.1 Conducting Nanomaterials
2.2 Nonconducting Nanomaterials: Magnetic Nanoparticles
3 Conception and Modeling of Amplification Effect in Nanomaterial-Based Enzyme Sensors
3.1 AuNPs-Based Amperometric Sensors
3.2 CNT-Based Amperometric Sensors
3.3 MNP-Based Amperometric Biosensors
3.4 Potentiometric Sensors
3.5 Conductometric and Impedimetric Biosensors
4 Conception and Modeling of Amplification Effect in Nanomaterial-Based Immunosensors
4.1 AuNP-Based Amperometric Immunosensors
4.2 AuNP-Based Potentiometric Sensors
4.3 Impedimetric Sensors
4.4 Conductometric Sensors
5 Conception and Modeling of Amplification Effect in Nanomaterial-Based DNA Biosensors
5.1 Amperometric Sensors
5.2 Impedimetric Sensors
6 Conclusion
References
8 ION-SENSITIVE FIELD-EFFECT TRANSISTORS WITH NANOSTRUCTURED CHANNELS AND NANOPARTICLE-MODIFIED GATE SURFACES: THEORY,MODELING AND ANALYSIS
V K. Khanna
1 Introduction
2 Structural Configurations of the Nanoscale ISFET
2.1 The Nanoporous Silicon ISFET
2.2 The CNT ISFET
2.3 The Si-NW ISFET
3 Physics of the Si-NW Biosensor
3.1 Basic Principle
3.2 Analogy with the Nanocantilever
3.3 Preliminary Analysis of Micro-ISFET Downscaling to Nano-ISFET
3.4 Single-Gate and Dual-Gate Nanowire Sensors
3.5 Energy-Band Model of the NW Sensor
4 Nair-Alam Model of Si-NW Biosensors
4.1 The Three Regions in the Biosensor
4.2 Computational Approach
4.3 Effect of Nanowire Diameter (d) on Sensitivity at Different Doping Densities, with Air as the Surrounding Medium
4.4 Effect of Nanowire Length (L) on Sensitivity at Different Doping Densities, with Air as the Surrounding Medium
4.5 Effect of the Fluidic Environment
4.6 Overall Model Implications
5 pH Response of Silicon Nanowires in Terms of the Site-Binding and Gouy-Chapman-Stern Models
6 Subthreshold Regime as the Optimal Sensitivity Regime of Nanowire Biosensors
7 Effective Capacitance Model for Apparent Surpassing of the Nernst Limit by Sensitivity of the Dual-Gate NW Sensor
8 Tunnel Field-Effect Transistor Concept
9 Role of Nanoparticles in ISFET Gate Functionalization
……
9 BIOSENSORS: MODELING AND SIMULATION OF DIFFUSION-LIMITED PROCESSES
INDEX
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