Buch, Englisch, 665 Seiten, Format (B × H): 158 mm x 243 mm, Gewicht: 1046 g
Reihe: Series in Sensors
Physical, Chemical, and Biological
Buch, Englisch, 665 Seiten, Format (B × H): 158 mm x 243 mm, Gewicht: 1046 g
Reihe: Series in Sensors
ISBN: 978-1-4398-2712-3
Verlag: Taylor & Francis Inc
After introducing nanosensor classification and fundamental terms, the book outlines the properties of important nanomaterials and nanotechnologies used in nanosensor fabrication. Subsequent chapters are organized according to nanosensor type: physical (mechanical and acoustical, thermal and radiation, optical, and magnetic); chemical (atomic and molecular energies); and biological. The final chapter summarizes the current state of the field and discusses future trends.
A complete and authoritative guide to nanosensors, this book offers up-to-date information on the fabrication, properties, and operating mechanisms of these fast and reliable sensors. It addresses progress in the field, fundamental issues and challenges facing researchers, and prospects for future development.
Zielgruppe
Researchers and graduate students in nanotechnology, engineering, physics, materials, and chemistry.
Autoren/Hrsg.
Fachgebiete
- Technische Wissenschaften Maschinenbau | Werkstoffkunde Maschinenbau Mechatronik, Mikrosysteme (MEMS), Nanosysteme
- Technische Wissenschaften Verfahrenstechnik | Chemieingenieurwesen | Biotechnologie Biotechnologie Biotechnologie: Mikrotechnologie, Nanobiotechnologie
- Naturwissenschaften Biowissenschaften Angewandte Biologie Biophysik
- Technische Wissenschaften Technik Allgemein Nanotechnologie
- Naturwissenschaften Chemie Physikalische Chemie Molekulare Chemische Nanostrukturen
- Technische Wissenschaften Elektronik | Nachrichtentechnik Elektronik Sensorik
- Naturwissenschaften Physik Angewandte Physik Biophysik
Weitere Infos & Material
Introduction to Nanosensors
Getting Started with Nanosensors
Natural Sciences
Physics
Chemistry
Biology
Semiconductor Electronics
Nanometer and Appreciation of Its Magnitude
Nanoscience and Nanotechnology
Nanomaterials and the Unusual Behavior at Nanoscales
Moving toward Sensors and Transducers: Meaning of Terms "Sensors" and "Transducers"
Definition of Sensor Parameters and Characteristics
Evolution of Semiconductor-Based Microsensors
From Macrosensor to Microsensor Age and Necessity of Nanoscale Measurements
Definition and Classification of Nanosensors
Physical, Chemical, and Biological Nanosensors
Some Examples of Nanosensors
Getting Familiar with Analytical and Characterization Tools: Microscopic Techniques to View Nanomaterials and Nanosensors
Spectroscopic Techniques for Analyzing Chemical Composition of Nanomaterials and Nanosensors
The Displacement Nanosensor: STM
The Force Nanosensor: AFM
Outline and Organization of the Book
Discussion and Conclusions
Materials for Nanosensors
Introduction
Nanoparticles or Nanoscale Particles, and Importance of the Intermediate Regime between Atoms and Molecules, and Bulk Matter
Classification of Nanoparticles on the Basis of Their Composition and Occurrence
Core/Shell-Structured Nanoparticles
Shape Dependence of Properties at Nanoscale
Dependence of Properties of Nanoparticles on Particle Size
Surface Energy of a Solid
Metallic Nanoparticles and Plasmons
Optical Properties of Bulk Metals and Metallic Nanoparticles
Parameters Controlling the Position of Surface Plasmon Band of Nanoparticles
Quantum Confinement
Quantum Dots
Carbon Nanotubes
Inorganic Nanowires
Nanoporous Materials
Discussion and Conclusions
Nanosensor Laboratory
Introduction
Nanotechnology Division
Micro- and Nanoelectronics Division
MEMS and NEMS Division
Biochemistry Division
Chemistry Division
Nanosensor Characterization Division
Nanosensor Powering, Signal Processing, and Communication Division
Discussion and Conclusions
Mechanical Nanosensors
Introduction
Nanogram Mass Sensing by Quartz Crystal Microbalance
Attogram (10-18 g) and Zeptogram (10-21 g) Mass Sensing by MEMS/NEMS Resonators
Electron Tunneling Displacement Nanosensor
Coulomb Blockade Electrometer-Based Displacement Nanosensor
Nanometer-Scale Displacement Sensing by Single-Electron Transistor
Magnetomotive Displacement Nanosensor
Piezoresistive and Piezoelectric Displacement Nanosensors
Optical Displacement Nanosensor
Femtonewton Force Sensors Using Doubly Clamped Suspended Carbon Nanotube Resonators
Suspended CNT Electromechanical Sensors for Displacement and Force
Membrane-Based CNT Electromechanical Pressure Sensor
Tunnel Effect Accelerometer
NEMS Accelerometer
Silicon Nanowire Accelerometer
CNT Flow Sensor for Ionic Solutions
Discussion and Conclusions
Thermal Nanosensors
Introduction
Nanoscale Thermocouple Formed by Tungsten and Platinum Nanosize Strips
Resistive Thermal Nanosensor Fabricated by Focused Ion Beam Chemical Vapor Deposition
"Carbon-Nanowire-on-Diamond" Resistive Temperature Nanosensor
Carbon Nanotube Grown on Nickel Film as Resistive Low-Temperature (10–300 K) Nanosensor
Laterally Grown CNT between Two Microelectrodes as Resistive Temperature Nanosensor
Silicon Nanowire Temperature Nanosensors: Resistors and Diode Structures
Ratiometric Fluorescent Nanoparticles for Temperature Sensing
Er3+/Yb3+ Co-Doped Gd2O3 Nano-Phosphor as Temperature Nanosensor Using Fluorescence Intensity Ratio Technique
Optical Heating of Yb3+–Er3+ Co-Doped Fluoride Nanoparticles and Distant Temperature Sensing through Luminescence
Porphyrin-Containing Copolymer as Thermochromic Nanosensor
Silicon-Micromachined Scanning Thermal Profiler
Superconducting Hot Electron Nanobolometers
Thermal Convective Accelerometer Using CNT Sensing Element
SWCNT Sensor for Airflow Measurement
Vacuum Pressure and Flow Velocity Sensors Using Batch-Processed CNT Wall
Nanogap Pirani Gauge
Carbon Nanotube–Polymer Nanocomposite as Conductivity Response Infrared Nanosensor
Nanocalorimetry
Discussion and Conclusions
Optical Nanosensors
Introduction
Noble-Metal Nanoparticles with LSPR and UV–Visible Spectroscopy
Nanosensors Based on Surface-Enhanced Raman Scattering
Colloidal SPR Colorimetric Gold Nanoparticle Spectrophotometric Sensor
Fiber-Optic Nanosensors
Nanograting-Based Optical Accelerometer
Fluorescent pH-Sensitive Nanosensors
Disadvantages of Optical Fiber and Fluorescent Nanosensors for Living Cell Studies
PEBBLE Nanosensors to Measure the Intracellular Environment
Quantum Dots as Fluorescent Labels
Quantum Dot FRET-Based Probes
Electrochemiluminescent Nanosensors for Remote Detection
Crossed Zinc Oxide Nanorods as Resistive UV Nanosensors
Discussion and Conclusions
Magnetic Nanosensors
Introduction
Magnetoresistance Sensors
Tunneling Magnetoresistance
Limitations, Advantages, and Applications of GMR and TMR Sensors
Magnetic Nanoparticle Probes for Studying Molecular Interactions
Protease-Specific Nanosensors for MRI
Magnetic Relaxation Switch Immunosensors
Magneto Nanosensor Microarray Biochip
Needle-Type SV-GMR Sensor for Biomedical Applications
Superconductive Magnetic Nanosensor
Electron Tunneling-Based Magnetic Field Sensor
Nanowire Magnetic Compass and Position Sensor
Discussion and Conclusions
Nanobiosensors
Introduction
Nanoparticle-Based Electrochemical Biosensors
CNT-Based Electrochemical Biosensors
Functionalization of CNTs for Biosensor Fabrication
Quantum Dot-Based Electrochemical Biosensors
Nanotube- and Nanowire-Based FET Nanobiosensors
Cantilever-Based Nanobiosensors
Optical Nanobiosensors
Biochips (or Microarrays)
Discussion and Conclusions
Chemical Nanosensors
Introduction
Gas Sensors Based on Nanomaterials
Metallic Nanoparticle-Based Gas Sensors
Metal Oxide Gas Sensors
Carbon Nanotube Gas Sensors
Porous Silicon-Based Gas Sensor
Thin Organic Polymer Film–Based Gas Sensors
Electrospun Polymer Nanofibers as Humidity Sensors
Toward Large Nanosensor Arrays and Nanoelectronic Nose
CNT-, Nanowire-, and Nanobelt-Based Chemical Nanosensors
Optochemical Nanosensors
Discussion and Conclusions
Future Trends of Nanosensors
Introduction
Scanning Tunneling Microscope
Atomic Force Microscope
Mechanical Nanosensors
Thermal Nanosensors
Optical Nanosensors
Magnetic Nanosensors
Nanobiosensors
Chemical Nanosensors
Nanosensor Fabrication Aspects
In Vivo Nanosensor Problems
Molecularly Imprinted Polymers for Biosensors
Interfacing Issues for Nanosensors: Power Consumption and Sample Delivery Problems
Depletion-Mediated Piezoelectric Actuation for NEMS
Discussion and Conclusions
Index
Review Exercises and References appear at the end of each chapter.
