Produktbild: Handbook of Measurement in Science and Engineering, Volume 3

Handbook of Measurement in Science and Engineering, Volume 3 Physics and Chemistry

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Produktdetails

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Gebundene Ausgabe

Erscheinungsdatum

25.04.2016

Herausgeber

Myer Kutz

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John Wiley & Sons

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Volume 3 edition

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Englisch

ISBN

978-1-118-64724-0

Beschreibung

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

25.04.2016

Herausgeber

Myer Kutz

Verlag

John Wiley & Sons

Seitenzahl

832

Maße (L/B/H)

25,7/18,3/4,3 cm

Gewicht

1588 g

Auflage

Volume 3 edition

Sprache

Englisch

ISBN

978-1-118-64724-0

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Libri GmbH
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DE

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  • Produktbild: Handbook of Measurement in Science and Engineering, Volume 3
  • VOLUME 3

    List of Contributors xxi

    PREFACE xxv

    Part VII Physics and Electrical Engineering 1943

    54 Laser Measurement Techniques 1945
    Cecil S. Joseph, Gargi Sharma, Thomas M. Goyette, and Robert H. Giles

    54.1 Introduction, 1945

    54.1.1 History and Development of the MASER, 1945

    54.1.2 Basic Laser Physics, 1946

    54.1.3 Laser Beam Characteristics, 1951

    54.1.4 Example: CO2 Laser Pumped Far¿Infrared Gas Laser Systems, 1956

    54.1.5 Heterodyned Detection, 1959

    54.1.6 Transformation of Multimode Laser Beams from THz Quantum Cascade Lasers, 1962

    54.1.7 Suggested Reading, 1965

    54.2 Laser Measurements: Laser¿Based Inverse Synthetic Aperture Radar Systems, 1965

    54.2.1 ISAR Theory, 1966

    54.2.2 DFT in Radar Imaging, 1967

    54.2.3 Signal Processing Considerations: Sampling Theory, 1970

    54.2.4 Measurement Calibration, 1971

    54.2.5 Example Terahertz Compact Radar Range, 1972

    54.2.6 Suggested Reading, 1974

    54.3 Laser Imaging Techniques, 1974

    54.3.1 Imaging System Measurement Parameters, 1975

    54.3.2 Terahertz Polarized Reflection Imaging of Nonmelanoma Skin Cancers, 1981

    54.3.3 Confocal Imaging, 1985

    54.3.4 Optical Coherence Tomography, 1987

    54.3.5 Femtosecond Laser Imaging, 1990

    54.3.6 Laser Raman Spectroscopy, 1996

    54.3.7 Suggested Reading, 1997

    References, 1997

    55 Magnetic Force Images Using Capacitive Coupling Effect 2001
    Byung I. Kim

    55.1 Introduction, 2001

    55.2 Experiment, 2004

    55.2.1 Principle, 2004

    55.2.2 Instrumentation, 2004

    55.2.3 Approach, 2005

    55.3 Results and Discussion, 2006

    55.3.1 Separation of Topographic Features from Magnetic Force Images Using Capacitive Coupling Effect, 2007

    55.3.2 Effects of Long¿Range Tip-Sample Interaction on Magnetic Force Imaging: A Comparative Study Between Bimorph¿Driven System and Electrostatic Force Modulation, 2012

    55.4 Conclusion, 2020

    References, 2021

    56 Scanning Tunneling Microscopy 2025
    Kwok¿Wai Ng

    56.1 Introduction, 2025

    56.2 Theory of Operation, 2026

    56.3 Measurement of the Tunnel Current, 2030

    56.4 The Scanner, 2032

    56.5 Operating Mode, 2035

    56.6 Coarse Approach Mechanism, 2036

    56.7 Summary, 2041

    References, 2042

    57 Measurement of Light and Color 2043
    John D. Bullough

    57.1 Introduction, 2043

    57.2 Lighting Terminology, 2043

    57.2.1 Fundamental Light and Color Terms, 2043

    57.2.2 Terms Describing the Amount and Distribution of Light, 2047

    57.2.3 Terms Describing Lighting Technologies and Performance, 2048

    57.2.4 Common Quantities Used in Lighting Specification, 2052

    57.3 Basic Principles of Photometry and Colorimetry, 2056

    57.3.1 Photometry, 2056

    57.3.2 Colorimetry, 2063

    57.4 Instrumentation, 2072

    57.4.1 Illuminance Meters, 2072

    57.4.2 Luminance Meters, 2072

    57.4.3 Spectroradiometers, 2074

    References, 2074

    58 The Detection and Measurement of Ionizing Radiation 2075
    Clair J. Sullivan

    58.1 Introduction, 2075

    58.2 Common Interactions of Ionizing Radiation, 2076

    58.2.1 Radiation Interactions, 2076

    58.3 The Measurement of Charge, 2077

    58.3.1 Counting Statistics, 2078

    58.3.2 The Two Measurement Modalities, 2080

    58.4 Major Types of Detectors, 2081

    58.4.1 Gas Detectors, 2081

    58.4.2 Ionization Chambers, 2086

    58.4.3 Proportional Counters, 2090

    58.4.4 GM Detectors, 2092

    58.4.5 Scintillators, 2092

    58.4.6 Readout of Scintillation Light, 2094

    58.4.7 Semiconductors, 2096

    58.5 Neutron Detection, 2100

    58.5.1 Thermal Neutron Detection, 2102

    58.5.2 Fast Neutron Detection, 2104

    58.6 Concluding Remarks, 2106

    References, 2106

    59 Measuring Time and Comparing Clocks 2109
    Judah Levine

    59.1 Introduction, 2109

    59.2 A Generic Clock, 2109

    59.3 Characterizing the Stability of Clocks and Oscillators, 2110

    59.3.1 Worst¿Case Analysis, 2111

    59.3.2 Statistical Analysis and the Allan Variance, 2113

    59.3.3 Limitations of the Statistics, 2116

    59.4 Characteristics of Different Types of Oscillators, 2117

    59.5 Comparing Clocks and Oscillators, 2119

    59.6 Noise Models, 2121

    59.6.1 White Phase Noise, 2121

    59.6.2 White Frequency Noise, 2122

    59.6.3 Long¿Period Effects: Frequency Aging, 2123

    59.6.4 Flicker Noise, 2124

    59.7 Measuring Tools and Methods, 2126

    59.8 Measurement Strategies, 2129

    59.9 The Kalman Estimator, 2133

    59.10 Transmitting Time and Frequency Information, 2135

    59.10.1 Modeling the Delay, 2136

    59.10.2 The Common¿View Method, 2137

    59.10.3 The "Melting¿Pot" Version of Common View, 2138

    59.10.4 Two¿Way Methods, 2139

    59.10.5 The Two¿Color Method, 2139

    59.11 Examples of the Measurement Strategies, 2141

    59.11.1 The Navigation Satellites of the GPS, 2141

    59.11.2 The One¿Way Method of Time Transfer: Modeling the Delay, 2144

    59.11.3 The Common¿View Method, 2145

    59.11.4 Two¿Way Time Protocols, 2147

    59.12 The Polling Interval: How Often Should I Calibrate a Clock?, 2152

    59.13 Error Detection, 2155

    59.14 Cost-Benefit Analysis, 2156

    59.15 The National Time Scale, 2157

    59.16 Traceability, 2158

    59.17 Summary, 2159

    59.18 Bibliography, 2160

    References, 2160

    60 Laboratory¿Based Gravity Measurement 2163
    Charles D. Hoyle, Jr.

    60.1 Introduction, 2163

    60.2 Motivation for Laboratory¿Scale Tests of Gravitational Physics, 2164

    60.3 Parameterization, 2165

    60.4 Current Status of Laboratory¿Scale Gravitational Measurements, 2166

    60.4.1 Tests of the ISL, 2166

    60.4.2 WEP Tests, 2167

    60.4.3 Measurements of G, 2167

    60.5 Torsion Pendulum Experiments, 2167

    60.5.1 General Principles and Sensitivity, 2168

    60.5.2 Fundamental Limitations, 2168

    60.5.3 ISL Experiments, 2171

    60.5.4 Future ISL Tests, 2172

    60.5.5 WEP Tests, 2176

    60.5.6 Measurements of G, 2176

    60.6 Microoscillators and Submicron Tests of Gravity, 2177

    60.6.1 Microcantilevers, 2177

    60.6.2 Very Short¿Range ISL Tests, 2177

    60.7 Atomic and Nuclear Physics Techniques, 2178

    Acknowledgements, 2178

    References, 2178

    61 Cryogenic Measurements 2181
    Ray Radebaugh

    61.1 Introduction, 2181

    61.2 Temperature, 2182

    61.2.1 ITS¿90 Temperature Scale and Primary Standards, 2182

    61.2.2 Commercial Thermometers, 2183

    61.2.3 Thermometer Use and Comparisons, 2193

    61.2.4 Dynamic Temperature Measurements, 2199

    61.3 Strain, 2201

    61.3.1 Metal Alloy Strain Gages, 2202

    61.3.2 Temperature Effects, 2203

    61.3.3 Magnetic Field Effects, 2204

    61.3.4 Measurement System, 2205

    61.3.5 Dynamic Measurements, 2205

    61.4 Pressure, 2205

    61.4.1 Capacitance Pressure Sensors, 2206

    61.4.2 Variable Reluctance Pressure Sensors, 2206

    61.4.3 Piezoresistive Pressure Sensors, 2208

    61.4.4 Piezoelectric Pressure Sensors, 2210

    61.5 Flow, 2211

    61.5.1 Positive Displacement Flowmeter (Volume Flow), 2212

    61.5.2 Angular Momentum Flowmeter (Mass Flow), 2212

    61.5.3 Turbine Flowmeter (Volume Flow), 2213

    61.5.4 Differential Pressure Flowmeter, 2213

    61.5.5 Thermal or Calorimetric (Mass Flow), 2216

    61.5.6 Hot¿Wire Anemometer (Mass Flow), 2217

    61.6 Liquid Level, 2218

    61.7 Magnetic Field, 2219

    61.8 Conclusions, 2220

    References, 2220

    62 Temperature¿Dependent Fluorescence Measurements 2225
    James E. Parks, Michael R. Cates, Stephen W. Allison, David L. Beshears, M. Al Akerman, and Matthew B. Scudiere

    62.1 Introduction, 2225

    62.2 Advantages of Phosphor Thermometry, 2227

    62.3 Theory and Background, 2227

    62.4 Laboratory Calibration of Tp Systems, 2235

    62.5 History of Phosphor Thermometry, 2238

    62.6 Representative Measurement Applications, 2239

    62.6.1 Permanent Magnet Rotor Measurement, 2239

    62.6.2 Turbine Engine Component Measurement, 2240

    62.7 Two¿Dimensional and Time¿Dependent Temperature Measurement, 2241

    62.8 Conclusion, 2243

    References, 2243

    63 Voltage and Current Transducers for Power Systems 2245
    Carlo Muscas and Nicola Locci

    63.1 Introduction, 2245

    63.2 Characterization of Voltage and Current Transducers, 2247

    63.3 Instrument Transformers, 2248

    63.3.1 Theoretical Fundamentals and Characteristics, 2248

    63.3.2 Instrument Transformers for Protective Purposes, 2252

    63.3.3 Instrument Transformers under Nonsinusoidal Conditions, 2253

    63.3.4 Capacitive Voltage Transformer, 2254

    63.4 Transducers Based on Passive Components, 2255

    63.4.1 Shunts, 2255

    63.4.2 Voltage Dividers, 2256

    63.4.3 Isolation Amplifiers, 2257

    63.5 Hall¿Effect and Zero¿Flux Transducers, 2258

    63.5.1 The Hall Effect, 2258

    63.5.2 Open¿Loop Hall¿Effect Transducers, 2259

    63.5.3 Closed¿Loop Hall¿Effect Transducers, 2259

    63.5.4 Zero¿Flux Transducers, 2262

    63.6 Air¿Core Current Transducers: Rogowski Coils, 2262

    63.7 Optical Current and Voltage Transducers, 2267

    63.7.1 Optical Current Transducers, 2268

    63.7.2 Optical Voltage Transducer, 2271

    63.7.3 Applications of OCTs and OVTs, 2272

    References and Further Reading, 2273

    64 Electric Power and Energy Measurement 2275
    Alessandro Ferrero and Marco Faifer

    64.1 Introduction, 2275

    64.2 Power and Energy in Electric Circuits, 2276

    64.2.1 DC Circuits, 2276

    64.2.2 AC Circuits, 2277

    64.3 Measurement Methods, 2282

    64.3.1 DC Conditions, 2282

    64.3.2 AC Conditions, 2285

    64.4 Wattmeters, 2288

    64.4.1 Architecture, 2288

    64.4.2 Signal Processing, 2289

    64.5 Transducers, 2290

    64.5.1 Current Transformers, 2291

    64.5.2 Hall¿Effect Sensors, 2296

    64.5.3 Rogowski Coils, 2297

    64.5.4 Voltage Transformers, 2299

    64.5.5 Electronic Transformers, 2302

    64.6 Power Quality Measurements, 2303

    References, 2305

    Part Viii CHEMISTRY 2307

    65 An Overview of Chemometrics for the Engineering and Measurement Sciences 2309
    Brad Swarbrick and Frank Westad

    65.1 Introduction: The Past and Present of Chemometrics, 2309

    65.2 Representative Data, 2311

    65.2.1 A Suggested Workflow for Developing Chemometric Models, 2313

    65.2.2 Accuracy and Precision, 2313

    65.2.3 Summary of Representative Data Principles, 2316

    65.3 Exploratory Data Analysis, 2317

    65.3.1 Univariate and Multivariate Analysis, 2317

    65.3.2 Cluster Analysis, 2318

    65.3.3 Principal Component Analysis, 2323

    65.4 Multivariate Regression, 2352

    65.4.1 General Principles of Univariate and Multivariate Regression, 2352

    65.4.2 Multiple Linear Regression, 2354

    65.4.3 Principal Component Regression, 2355

    65.4.4 Partial Least Squares Regression, 2356

    65.5 Multivariate Classification, 2369

    65.5.1 Linear Discriminant Analysis, 2370

    65.5.2 Soft Independent Modeling of Class Analogy, 2372

    65.5.3 Partial Least Squares Discriminant Analysis, 2381

    65.5.4 Support Vector Machine Classification, 2383

    65.6 Techniques for Validating Chemometric Models, 2385

    65.6.1 Test Set Validation, 2386

    65.6.2 Cross Validation, 2388

    65.7 An Introduction to Mspc, 2389

    65.7.1 Multivariate Projection, 2389

    65.7.2 Hotelling's T2 Control Chart, 2390

    65.7.3 Q¿Residuals, 2391

    65.7.4 Influence Plot, 2391

    65.7.5 Continuous versus Batch Monitoring, 2392

    65.7.6 Implementing MSPC in Practice, 2394

    65.8 Terminology, 2397

    65.9 Chapter Summary, 2401

    References, 2404

    66 Liquid Chromatography 2409
    Zhao Li, Sandya Beeram, Cong Bi, Ellis Kaufmann, Ryan Matsuda, Maria Podariu, Elliott Rodriguez, Xiwei Zheng, and David S. Hage

    66.1 Introduction, 2409

    66.2 Support Materials in Lc, 2412

    66.3 Role of the Mobile Phase in Lc, 2413

    66.4 Adsorption Chromatography, 2414

    66.5 Partition Chromatography, 2415

    66.6 Ion¿Exchange Chromatography, 2417

    66.7 Size¿Exclusion Chromatography, 2419

    66.8 Affinity Chromatography, 2421

    66.9 Detectors for Liquid Chromatography, 2423

    66.10 Other Components of Lc Systems, 2426

    Acknowledgements, 2427

    References, 2427

    67 Mass Spectroscopy Measurements of Nitrotyrosine¿Containing Proteins 2431
    Xianquan Zhan and Dominic M. Desiderio

    67.1 Introduction, 2431

    67.1.1 Formation, Chemical Properties, and Related Nomenclature of Tyrosine Nitration, 2431

    67.1.2 Biological Roles of Tyrosine Nitration in a Protein, 2432

    67.1.3 Challenge and Strategies to Identify a Nitroprotein with Mass Spectrometry, 2432

    67.1.4 Biological Significance Measurement of Nitroproteins, 2434

    67.2 Mass Spectrometric Characteristics of Nitropeptides, 2434

    67.2.1 MALDI¿MS Spectral Characteristics of a Nitropeptide, 2434

    67.2.2 ESI¿MS Spectral Characteristics of a Nitropeptide, 2437

    67.2.3 Optimum Collision Energy for Ion Fragmentation and Detection Sensitivity for a Nitropeptide, 2438

    67.2.4 MS/MS Spectral Characteristics of a Nitropeptide under Different Ion¿Fragmentation Models, 2440

    67.3 Ms Measurement of in vitro Synthetic Nitroproteins, 2443

    67.3.1 Importance of Measurement of In Vitro Synthetic Nitroproteins, 2443

    67.3.2 Commonly Used In Vitro Nitroproteins and Their Preparation, 2443

    67.3.3 Methods Used to Measure in Vitro Synthetic Nitroproteins, 2444

    67.4 Ms Measurement of In Vivo Nitroproteins, 2446

    67.4.1 Importance of Isolation and Enrichment of In Vivo Nitroprotein/Nitropeptide Prior to MS Analysis, 2446

    67.4.2 Methods Used to Isolate and Enrich In Vivo Nitroproteins/Nitropeptides, 2446

    67.5 Ms Measurement of In Vivo Nitroproteins in Different Pathological Conditions, 2449

    67.6 Biological Function Measurement of Nitroproteins, 2456

    67.6.1 Literature DatäBased Rationalization of Biological Functions, 2457

    67.6.2 Protein Domain and Motif Analyses, 2459

    67.6.3 Systems Pathway Analysis, 2459

    67.6.4 Structural Biology Analysis, 2460

    67.7 Pitfalls of Nitroprotein Measurement, 2462

    67.8 Conclusions, 2463

    Nomenclature, 2464

    Acknowledgments, 2465

    References, 2465

    68 Fluorescence Spectroscopy 2475
    Yevgen Povrozin and Beniamino Barbieri

    68.1 Observables Measured in Fluorescence, 2476

    68.2 The Perrin-Jab¿on¿ski Diagram, 2476

    68.3 Instrumentation, 2479

    68.3.1 Light Source, 2480

    68.3.2 Monochromator, 2480

    68.3.3 Light Detectors, 2481

    68.3.4 Instrumentation for Steady¿State Fluorescence: Analog and Photon Counting, 2483

    68.3.5 The Measurement of Decay Times: Frequency¿Domain and Time¿Domain Techniques, 2484

    68.4 Fluorophores, 2486

    68.5 Measurements, 2487

    68.5.1 Excitation Spectrum, 2487

    68.5.2 Emission Spectrum, 2488

    68.5.3 Decay Times of Fluorescence, 2490

    68.5.4 Quantum Yield, 2492

    68.5.5 Anisotropy and Polarization, 2492

    68.6 Conclusions, 2498

    References, 2498

    Further Reading, 2498

    69 X¿Ray Absorption Spectroscopy 2499
    Grant Bunker

    69.1 Introduction, 2499

    69.2 Basic Physics of X¿Rays, 2499

    69.2.1 Units, 2500

    69.2.2 X¿Ray Photons and Their Properties, 2500

    69.2.3 X¿Ray Scattering and Diffraction, 2501

    69.2.4 X¿Ray Absorption, 2502

    69.2.5 Cross Sections and Absorption Edges, 2503

    69.3 Experimental Requirements, 2505

    69.4 Measurement Modes, 2507

    69.5 Sources, 2507

    69.5.1 Laboratory Sources, 2507

    69.5.2 Synchrotron Radiation Sources, 2508

    69.5.3 Bend Magnet Radiation, 2509

    69.5.4 Insertion Devices: Wigglers and Undulators, 2509

    69.6 Beamlines, 2512

    69.6.1 Instrument Control and Scanning Modes, 2512

    69.6.2 Double¿Crystal Monochromators, 2513

    69.6.3 Focusing Conditions, 2514

    69.6.4 X¿Ray Lenses and Mirrors, 2515

    69.6.5 Harmonics, 2516

    69.7 Detectors, 2518

    69.7.1 Ionization Chambers and PIN Diodes, 2519

    69.7.2 Solid¿State Detectors, SDDs, and APDs, 2520

    69.8 Sample Preparation and Detection Modes, 2521

    69.8.1 Transmission Mode, 2521

    69.8.2 Fluorescence Mode, 2521

    69.8.3 HALO, 2522

    69.8.4 Sample Geometry and Background Rejection, 2523

    69.8.5 Oriented Samples, 2525

    69.9 Absolute Measurements, 2526

    References, 2526

    70 Nuclear Magnetic Resonance (NMR) Spectroscopy 2529
    Kenneth R. Metz

    70.1 Introduction, 2529

    70.2 Historical Review, 2530

    70.3 Basic Principles of Spin Magnetization, 2531

    70.4 Exciting the NMR Signal, 2534

    70.5 Detecting the NMR Signal, 2538

    70.6 Computing the NMR Spectrum, 2540

    70.7 NMR Instrumentation, 2542

    70.8 The Basic Pulsed FTNMR Experiment, 2550

    70.9 Characteristics of NMR Spectra, 2551

    70.9.1 The Chemical Shift, 2552

    70.9.2 Spin-Spin Coupling, 2557

    70.10 NMR Relaxation Effects, 2563

    70.10.1 Spin-Lattice Relaxation, 2563

    70.10.2 Spin-Spin Relaxation, 2565

    70.10.3 Quantitative Analysis by NMR, 2568

    70.11 Dynamic Phenomena in NMR, 2568

    70.12 Multidimensional NMR, 2573

    70.13 Conclusion, 2580

    References, 2580

    71 Near¿Infrared Spectroscopy and Its Role in Scientific and Engineering Applications 2583
    Brad Swarbrick

    71.1 Introduction to Near¿Infrared Spectroscopy and Historical Perspectives, 2583

    71.1.1 A Brief Overview of Near¿Infrared Spectroscopy and Its Usage, 2583

    71.1.2 A Short History of NIR, 2585

    71.2 The Theory behind Nir Spectroscopy, 2588

    71.2.1 IR Radiation, 2588

    71.2.2 The Mechanism of Interaction of NIR Radiation with Matter, 2588

    71.2.3 Absorbance Spectra, 2591

    71.3 Instrumentation for Nir Spectroscopy, 2595

    71.3.1 General Configuration of Instrumentation, 2595

    71.3.2 Filter¿Based Instruments, 2597

    71.3.3 Holographic Grating¿Based Instruments, 2598

    71.3.4 Stationary Spectrographic Instruments, 2600

    71.3.5 Fourier Transform Instruments, 2601

    71.3.6 Acoustooptical Tunable Filter Instruments, 2603

    71.3.7 Microelectromechanical Spectrometers, 2604

    71.3.8 Linear Variable Filter Instruments, 2605

    71.3.9 A Brief Overview of Detectors Used for NIR Spectroscopy, 2606

    71.3.10 Summary, 2608

    71.4 Modes of Spectral Collection and Sample Preparation in Nir Spectroscopy, 2609

    71.4.1 Transmission Mode, 2609

    71.4.2 Diffuse Reflectance, 2611

    71.4.3 Sample Preparation, 2613

    71.4.4 Fiber Optic Probes, 2617

    71.4.5 Summary of Sampling Methods, 2619

    71.5 Preprocessing of Nir Spectra for Chemometric Analysis, 2620

    71.5.1 Preprocessing of NIR Spectra, 2621

    71.5.2 Minimizing Additive Effects, 2621

    71.5.3 Minimizing Multiplicative Effects, 2627

    71.5.4 Preprocessing Summary, 2633

    71.6 A Brief Overview of Applications of Nir Spectroscopy, 2633

    71.6.1 Agricultural Applications, 2634

    71.6.2 Pharmaceutical/Biopharmaceutical Applications, 2636

    71.6.3 Applications in the Petrochemical and Refining Sectors, 2644

    71.6.4 Applications in the Food and Beverage Industries, 2646

    71.7 Summary and Future Perspectives, 2647

    71.8 Terminology, 2648

    References, 2652

    72 Nanomaterials Properties 2657
    Paul J. Simmonds

    72.1 Introduction, 2657

    72.2 The Rise of Nanomaterials, 2660

    72.3 Nanomaterial Properties Resulting from High Surface¿Areäto¿Volume Ratio, 2661

    72.3.1 The Importance of Surfaces in Nanomaterials, 2661

    72.3.2 Electrostatic and Van der Waals Forces, 2662

    72.3.3 Color, 2663

    72.3.4 Melting Point, 2663

    72.3.5 Magnetism, 2664

    72.3.6 Hydrophobicity and Surface Energetics, 2664

    72.3.7 Nanofluidics, 2666

    72.3.8 Nanoporosity, 2668

    72.3.9 Nanomembranes, 2669

    72.3.10 Nanocatalysis, 2670

    72.3.11 Further Increasing the SAV Ratio, 2671

    72.3.12 Nanopillars, 2672

    72.3.13 Nanomaterial Functionalization, 2673

    72.3.14 Other Applications for High SAV Ratio Nanomaterials, 2674

    72.4 Nanomaterial Properties Resulting from Quantum Confinement, 2674

    72.4.1 Quantum Well Nanostructures, 2677

    72.4.2 Quantum Wire Nanostructures, 2682

    72.4.3 Quantum Dot Nanostructures, 2691

    72.5 Conclusions, 2695

    References, 2695

    73 Chemical Sensing 2707
    W. Rudolf Seitz

    73.1 Introduction, 2707

    73.2 Electrical Methods, 2709

    73.2.1 Potentiometry, 2709

    73.2.2 Voltammetry, 2713

    73.2.3 Chemiresistors, 2715

    73.2.4 Field Effect Transistors, 2716

    73.3 Optical Methods, 2717

    73.3.1 In situ Optical Measurements, 2717

    73.3.2 Raman Spectroscopy, 2719

    73.3.3 Indicator¿Based Optical Sensors, 2721

    73.4 Mass Sensors, 2722

    73.5 Sensor Arrays (Electronic Nose), 2724

    References, 2724

    Index 2727