Wendong Zhang, Xing Fu, Dachao Li, Jijun Xiong, Chenyang Xue, Xiujian Chou
Measurement Technology for Micro-Nanometer Devices
Wendong Zhang, Xing Fu, Dachao Li, Jijun Xiong, Chenyang Xue, Xiujian Chou
Measurement Technology for Micro-Nanometer Devices
- Gebundenes Buch
- Merkliste
- Auf die Merkliste
- Bewerten Bewerten
- Teilen
- Produkt teilen
- Produkterinnerung
- Produkterinnerung
A fully comprehensive examination of state-of-the-art technologies for measurement at the small scale
- Highlights the advanced research work from industry and academia in micro-nano devices test technology - Written at both introductory and advanced levels, provides the fundamentals and theories - Focuses on the measurement techniques for characterizing MEMS/NEMS devices - Companion website includes Lab View soft, micro-vision system test software, and algorithm software, enhancing the learning experience
Andere Kunden interessierten sich auch für
- Kyunghwan OhSilica Optical Fiber Technology for Devices and Components138,99 €
- Fabio CasciatiTechnology of Semiactive Devices and Applications in Vibration Mitigation159,99 €
- Ludwig MichalskiTemperature Measurement494,99 €
- Myer KutzHandbook of Measurement in Science and Engineering, 2 Volume Set768,99 €
- José RodriguezPredictive Control of Power Converters and Electrical Drives164,99 €
- Dennis W PratherPhotonic Crystals, Theory, Applications and Fabrication194,99 €
- Robert L. WilliamsLinear State-Space Control Systems166,99 €
-
-
-
A fully comprehensive examination of state-of-the-art technologies for measurement at the small scale
- Highlights the advanced research work from industry and academia in micro-nano devices test technology
- Written at both introductory and advanced levels, provides the fundamentals and theories
- Focuses on the measurement techniques for characterizing MEMS/NEMS devices
- Companion website includes Lab View soft, micro-vision system test software, and algorithm software, enhancing the learning experience
- Highlights the advanced research work from industry and academia in micro-nano devices test technology
- Written at both introductory and advanced levels, provides the fundamentals and theories
- Focuses on the measurement techniques for characterizing MEMS/NEMS devices
- Companion website includes Lab View soft, micro-vision system test software, and algorithm software, enhancing the learning experience
Produktdetails
- Produktdetails
- Verlag: Wiley & Sons
- 1. Auflage
- Seitenzahl: 352
- Erscheinungstermin: 18. März 2017
- Englisch
- Abmessung: 244mm x 168mm x 20mm
- Gewicht: 680g
- ISBN-13: 9781118717967
- ISBN-10: 1118717961
- Artikelnr.: 43092209
- Verlag: Wiley & Sons
- 1. Auflage
- Seitenzahl: 352
- Erscheinungstermin: 18. März 2017
- Englisch
- Abmessung: 244mm x 168mm x 20mm
- Gewicht: 680g
- ISBN-13: 9781118717967
- ISBN-10: 1118717961
- Artikelnr.: 43092209
WENDONG ZHANG, North University of China, China XIUJIAN CHOU, North University of China, China TIELIN SHI, Huazhong University of Science and Technology, China ZONGMIN MA, North University of China, China HAIFEI BAO, Shanghai Institute of Microsystem and Information Technology, Chinese Academy of Sciences, China JING CHEN, Peking University, China LIGUO CHEN, Soochow University, China DACHAO LI, Tianjin University, China CHENYANG XUE, Key Laboratory of Instrument Science and Dynamic Measurement, Ministry of Education, China
About the Authors ix Preface xi 1 Introduction 1 1.1 Micro/Nanotechnology 1
1.1.1 Development of MEMS 1 1.1.2 Development of NEMS 3 1.2 Development of
Micro/Nanoscale Measurements 5 1.2.1 Significance 5 1.2.2 Types of
Micro/Nanoscale Measurements 6 1.2.3 Conclusion and Outlook 7 References 9
2 Geometry Measurements at the Micro/Nanoscale 11 2.1 Microvision
Measurement 11 2.1.1 Micro/Nanoscale Plane Geometry Parameter Tests 11
2.1.2 Integrality Tests and Analysis of Micro/Nanometer Structures 12 2.1.3
Micro/Nanoscale Plane Dynamic Characteristic Tests 13 2.2 3D Morphology
Measurements in Contact Mode 15 2.2.1 Scanning Probe Microscopy 15 2.2.2
Near-Field Scan Optics Microscopy (NSOM) 21 2.2.3 Scanning Electron
Microscopy 26 2.2.4 Transmission Electron Microscopy 31 2.3 3D Morphology
Optics Measurements with Non-Contact Modes 36 2.3.1 Laser Scanning
Microscopy 37 2.3.2 White Light Interferometry Morphology Measurements 40
2.4 Micro/Nanoscale Tricoordinate Measurements 63 2.4.1 Basics 64 2.4.2
Experimental Techniques 67 2.5 Measurement of Film Thickness 71 References
77 3 Dynamic Measurements at the Micro/Nanoscale 79 3.1 Stroboscopic
Dynamic Vision Imaging 79 3.1.1 Principles of Plane Dynamic Measurements 80
3.1.2 Equipment 81 3.1.3 Block Matching and Phase Correlation Methods 84
3.1.4 Optical Flow Field Measurement Method 86 3.2 Stroboscopic Microscopy
Interference Measurements 90 3.2.1 Principles 90 3.2.2 Equipment 92 3.2.3
System 93 3.3 Laser Doppler Microscope Vibration Measurements 94 3.3.1
Differential Doppler Vibration Measurements 98 3.3.2 Laser Torsional
Vibration Measurements 99 3.3.3 Laser Doppler Vibration Measurements of
Single Torsional Vibrations and Single Bend Vibrations 100 3.3.4 Laser
Doppler Flutter Measurements 103 3.4 Conclusion 104 3.4.1 Mechanical
Processes in AFM 104 3.4.2 Measurement Theory and Methods of
Micro/Nanometer Mechanics in AFM 106 3.4.3 Micro/Nano Measurement System
and Reference Cantilever Measurement Method in AFM 112 3.4.4 Measurement of
Spring Constant of Cantilever and System Verification 115 3.4.5 Application
of AFM to Nanometrology 117 References 119 4 Mechanical Characteristics
Measurements 121 4.1 Residual Stress Measurements of Microstructures 122
4.1.1 Residual Stress 122 4.1.2 Measurements 122 4.2 Axial Tensile
Measurement 131 4.2.1 Traditional Tensile Method 131 4.2.2 Conversion
Tensile Method 136 4.2.3 Integrated Tensile Method 137 4.2.4 Displacement
Measurement of Uniaxial Tension 138 4.3 Nano-Indentation Measurements Using
Contact Dode 140 4.3.1 Basic Principles of Nano-Indentation Technology 140
4.3.2 Nano-Indentation Measurements 148 4.3.3 Features of Nano-Indentation
Technology 150 4.4 Bend Method 151 4.4.1 Principles 151 4.4.2
Micro/Nanobeams 154 4.4.3 Advantages and Disadvantages of the Bend Method
157 4.5 Resonance Method 157 4.5.1 Resonance Frequency 158 4.5.2 Intrinsic
Resonance Frequency 159 4.6 Stress Measurements Based on Raman Spectroscopy
160 4.6.1 Raman Scattering 160 4.6.2 Theory 161 4.6.3 Experimental
Techniques 162 4.6.4 System 164 4.6.5 Experiments 172 4.6.6 Conclusion and
Prospects 173 4.7 Bonding Strength Measurements 174 4.7.1 Principles 174
4.7.2 Crack Spread Method 183 References 189 5 SPM for MEMS/NEMS
Measurements 191 5.1 Introduction 191 5.2 Atomic Force Measurement 192
5.2.1 Atomic Force Measurement Methods 192 5.3 Instruments 199 5.3.1
Schematic of the AFM Unit 199 5.3.2 Fiber and Sample Approach Stages 200
5.3.3 Tube Scanner 202 5.3.4 Vibration Isolation System 204 5.4
Interferometer Detection Method 205 5.4.1 Optical Interference Theory 205
5.4.2 Interferometer Detection 207 5.5 Cantilever and Tip 209 5.6 SPM
System 211 5.7 Applications of SFM in Micro/Nano Measurements 212 5.7.1
Three-Dimensional (3D) Imaging 212 5.7.2 Micro/Nanoelectronics 215 5.7.3
Metrology 217 5.7.4 Manipulation and Spectroscopy 218 5.8 Conclusion 222
References 222 6 MEMS Online Measurements 227 6.1 Bulk Silicon
Micromachining 228 6.1.1 Principles 228 6.1.2 Location Platform 229 6.2
Surface Micromachining 235 6.2.1 Surface Sacrificial Layer Microfabrication
Process 236 6.2.2 Thermal Conductivity Measurements of Polysilicon Thin
Films 239 6.3 Polymer Materials Processing 245 6.3.1 Principles 245 6.3.2
Photosensitive Polyimide (PSPI) Microvalve 247 6.4 Conclusion 252
References 253 7 Typical Micro/Nanoscale Device Measurements 255 7.1 MEMS
Pressure Transducer Measurements 255 7.1.1 Introduction 255 7.1.2
Principles of MEMS Pressure Transducers 255 7.1.3 Electrical Property
Measurements 261 7.1.4 Static Testing of MEMS Pressure Sensors 267 7.1.5
Dynamic Measurements 271 7.1.6 Impact Factors of Pressure Sensor Testing
272 7.1.7 Reliability Measurements 273 7.2 MEMS Accelerator Measurements
276 7.2.1 Introduction 276 7.2.2 Low- and Medium-Range Accelerator
Measurements 277 7.2.3 High-g MEMS Accelerator Measurements 284 7.3 RF MEMS
Testing Technology 296 7.4 Micro/Nanoscale Devices for Infrared Measurement
304 7.4.1 Infrared Imaging System 305 7.4.2 Infrared Imaging Measurement
307 7.5 Typical NEMS Device Measurement 311 7.5.1 NEMS Accelerometer
Measurements 312 7.5.2 Working Principles of a NEMS Acoustic Sensor 318
References 325 Index 327
1.1.1 Development of MEMS 1 1.1.2 Development of NEMS 3 1.2 Development of
Micro/Nanoscale Measurements 5 1.2.1 Significance 5 1.2.2 Types of
Micro/Nanoscale Measurements 6 1.2.3 Conclusion and Outlook 7 References 9
2 Geometry Measurements at the Micro/Nanoscale 11 2.1 Microvision
Measurement 11 2.1.1 Micro/Nanoscale Plane Geometry Parameter Tests 11
2.1.2 Integrality Tests and Analysis of Micro/Nanometer Structures 12 2.1.3
Micro/Nanoscale Plane Dynamic Characteristic Tests 13 2.2 3D Morphology
Measurements in Contact Mode 15 2.2.1 Scanning Probe Microscopy 15 2.2.2
Near-Field Scan Optics Microscopy (NSOM) 21 2.2.3 Scanning Electron
Microscopy 26 2.2.4 Transmission Electron Microscopy 31 2.3 3D Morphology
Optics Measurements with Non-Contact Modes 36 2.3.1 Laser Scanning
Microscopy 37 2.3.2 White Light Interferometry Morphology Measurements 40
2.4 Micro/Nanoscale Tricoordinate Measurements 63 2.4.1 Basics 64 2.4.2
Experimental Techniques 67 2.5 Measurement of Film Thickness 71 References
77 3 Dynamic Measurements at the Micro/Nanoscale 79 3.1 Stroboscopic
Dynamic Vision Imaging 79 3.1.1 Principles of Plane Dynamic Measurements 80
3.1.2 Equipment 81 3.1.3 Block Matching and Phase Correlation Methods 84
3.1.4 Optical Flow Field Measurement Method 86 3.2 Stroboscopic Microscopy
Interference Measurements 90 3.2.1 Principles 90 3.2.2 Equipment 92 3.2.3
System 93 3.3 Laser Doppler Microscope Vibration Measurements 94 3.3.1
Differential Doppler Vibration Measurements 98 3.3.2 Laser Torsional
Vibration Measurements 99 3.3.3 Laser Doppler Vibration Measurements of
Single Torsional Vibrations and Single Bend Vibrations 100 3.3.4 Laser
Doppler Flutter Measurements 103 3.4 Conclusion 104 3.4.1 Mechanical
Processes in AFM 104 3.4.2 Measurement Theory and Methods of
Micro/Nanometer Mechanics in AFM 106 3.4.3 Micro/Nano Measurement System
and Reference Cantilever Measurement Method in AFM 112 3.4.4 Measurement of
Spring Constant of Cantilever and System Verification 115 3.4.5 Application
of AFM to Nanometrology 117 References 119 4 Mechanical Characteristics
Measurements 121 4.1 Residual Stress Measurements of Microstructures 122
4.1.1 Residual Stress 122 4.1.2 Measurements 122 4.2 Axial Tensile
Measurement 131 4.2.1 Traditional Tensile Method 131 4.2.2 Conversion
Tensile Method 136 4.2.3 Integrated Tensile Method 137 4.2.4 Displacement
Measurement of Uniaxial Tension 138 4.3 Nano-Indentation Measurements Using
Contact Dode 140 4.3.1 Basic Principles of Nano-Indentation Technology 140
4.3.2 Nano-Indentation Measurements 148 4.3.3 Features of Nano-Indentation
Technology 150 4.4 Bend Method 151 4.4.1 Principles 151 4.4.2
Micro/Nanobeams 154 4.4.3 Advantages and Disadvantages of the Bend Method
157 4.5 Resonance Method 157 4.5.1 Resonance Frequency 158 4.5.2 Intrinsic
Resonance Frequency 159 4.6 Stress Measurements Based on Raman Spectroscopy
160 4.6.1 Raman Scattering 160 4.6.2 Theory 161 4.6.3 Experimental
Techniques 162 4.6.4 System 164 4.6.5 Experiments 172 4.6.6 Conclusion and
Prospects 173 4.7 Bonding Strength Measurements 174 4.7.1 Principles 174
4.7.2 Crack Spread Method 183 References 189 5 SPM for MEMS/NEMS
Measurements 191 5.1 Introduction 191 5.2 Atomic Force Measurement 192
5.2.1 Atomic Force Measurement Methods 192 5.3 Instruments 199 5.3.1
Schematic of the AFM Unit 199 5.3.2 Fiber and Sample Approach Stages 200
5.3.3 Tube Scanner 202 5.3.4 Vibration Isolation System 204 5.4
Interferometer Detection Method 205 5.4.1 Optical Interference Theory 205
5.4.2 Interferometer Detection 207 5.5 Cantilever and Tip 209 5.6 SPM
System 211 5.7 Applications of SFM in Micro/Nano Measurements 212 5.7.1
Three-Dimensional (3D) Imaging 212 5.7.2 Micro/Nanoelectronics 215 5.7.3
Metrology 217 5.7.4 Manipulation and Spectroscopy 218 5.8 Conclusion 222
References 222 6 MEMS Online Measurements 227 6.1 Bulk Silicon
Micromachining 228 6.1.1 Principles 228 6.1.2 Location Platform 229 6.2
Surface Micromachining 235 6.2.1 Surface Sacrificial Layer Microfabrication
Process 236 6.2.2 Thermal Conductivity Measurements of Polysilicon Thin
Films 239 6.3 Polymer Materials Processing 245 6.3.1 Principles 245 6.3.2
Photosensitive Polyimide (PSPI) Microvalve 247 6.4 Conclusion 252
References 253 7 Typical Micro/Nanoscale Device Measurements 255 7.1 MEMS
Pressure Transducer Measurements 255 7.1.1 Introduction 255 7.1.2
Principles of MEMS Pressure Transducers 255 7.1.3 Electrical Property
Measurements 261 7.1.4 Static Testing of MEMS Pressure Sensors 267 7.1.5
Dynamic Measurements 271 7.1.6 Impact Factors of Pressure Sensor Testing
272 7.1.7 Reliability Measurements 273 7.2 MEMS Accelerator Measurements
276 7.2.1 Introduction 276 7.2.2 Low- and Medium-Range Accelerator
Measurements 277 7.2.3 High-g MEMS Accelerator Measurements 284 7.3 RF MEMS
Testing Technology 296 7.4 Micro/Nanoscale Devices for Infrared Measurement
304 7.4.1 Infrared Imaging System 305 7.4.2 Infrared Imaging Measurement
307 7.5 Typical NEMS Device Measurement 311 7.5.1 NEMS Accelerometer
Measurements 312 7.5.2 Working Principles of a NEMS Acoustic Sensor 318
References 325 Index 327
About the Authors ix Preface xi 1 Introduction 1 1.1 Micro/Nanotechnology 1
1.1.1 Development of MEMS 1 1.1.2 Development of NEMS 3 1.2 Development of
Micro/Nanoscale Measurements 5 1.2.1 Significance 5 1.2.2 Types of
Micro/Nanoscale Measurements 6 1.2.3 Conclusion and Outlook 7 References 9
2 Geometry Measurements at the Micro/Nanoscale 11 2.1 Microvision
Measurement 11 2.1.1 Micro/Nanoscale Plane Geometry Parameter Tests 11
2.1.2 Integrality Tests and Analysis of Micro/Nanometer Structures 12 2.1.3
Micro/Nanoscale Plane Dynamic Characteristic Tests 13 2.2 3D Morphology
Measurements in Contact Mode 15 2.2.1 Scanning Probe Microscopy 15 2.2.2
Near-Field Scan Optics Microscopy (NSOM) 21 2.2.3 Scanning Electron
Microscopy 26 2.2.4 Transmission Electron Microscopy 31 2.3 3D Morphology
Optics Measurements with Non-Contact Modes 36 2.3.1 Laser Scanning
Microscopy 37 2.3.2 White Light Interferometry Morphology Measurements 40
2.4 Micro/Nanoscale Tricoordinate Measurements 63 2.4.1 Basics 64 2.4.2
Experimental Techniques 67 2.5 Measurement of Film Thickness 71 References
77 3 Dynamic Measurements at the Micro/Nanoscale 79 3.1 Stroboscopic
Dynamic Vision Imaging 79 3.1.1 Principles of Plane Dynamic Measurements 80
3.1.2 Equipment 81 3.1.3 Block Matching and Phase Correlation Methods 84
3.1.4 Optical Flow Field Measurement Method 86 3.2 Stroboscopic Microscopy
Interference Measurements 90 3.2.1 Principles 90 3.2.2 Equipment 92 3.2.3
System 93 3.3 Laser Doppler Microscope Vibration Measurements 94 3.3.1
Differential Doppler Vibration Measurements 98 3.3.2 Laser Torsional
Vibration Measurements 99 3.3.3 Laser Doppler Vibration Measurements of
Single Torsional Vibrations and Single Bend Vibrations 100 3.3.4 Laser
Doppler Flutter Measurements 103 3.4 Conclusion 104 3.4.1 Mechanical
Processes in AFM 104 3.4.2 Measurement Theory and Methods of
Micro/Nanometer Mechanics in AFM 106 3.4.3 Micro/Nano Measurement System
and Reference Cantilever Measurement Method in AFM 112 3.4.4 Measurement of
Spring Constant of Cantilever and System Verification 115 3.4.5 Application
of AFM to Nanometrology 117 References 119 4 Mechanical Characteristics
Measurements 121 4.1 Residual Stress Measurements of Microstructures 122
4.1.1 Residual Stress 122 4.1.2 Measurements 122 4.2 Axial Tensile
Measurement 131 4.2.1 Traditional Tensile Method 131 4.2.2 Conversion
Tensile Method 136 4.2.3 Integrated Tensile Method 137 4.2.4 Displacement
Measurement of Uniaxial Tension 138 4.3 Nano-Indentation Measurements Using
Contact Dode 140 4.3.1 Basic Principles of Nano-Indentation Technology 140
4.3.2 Nano-Indentation Measurements 148 4.3.3 Features of Nano-Indentation
Technology 150 4.4 Bend Method 151 4.4.1 Principles 151 4.4.2
Micro/Nanobeams 154 4.4.3 Advantages and Disadvantages of the Bend Method
157 4.5 Resonance Method 157 4.5.1 Resonance Frequency 158 4.5.2 Intrinsic
Resonance Frequency 159 4.6 Stress Measurements Based on Raman Spectroscopy
160 4.6.1 Raman Scattering 160 4.6.2 Theory 161 4.6.3 Experimental
Techniques 162 4.6.4 System 164 4.6.5 Experiments 172 4.6.6 Conclusion and
Prospects 173 4.7 Bonding Strength Measurements 174 4.7.1 Principles 174
4.7.2 Crack Spread Method 183 References 189 5 SPM for MEMS/NEMS
Measurements 191 5.1 Introduction 191 5.2 Atomic Force Measurement 192
5.2.1 Atomic Force Measurement Methods 192 5.3 Instruments 199 5.3.1
Schematic of the AFM Unit 199 5.3.2 Fiber and Sample Approach Stages 200
5.3.3 Tube Scanner 202 5.3.4 Vibration Isolation System 204 5.4
Interferometer Detection Method 205 5.4.1 Optical Interference Theory 205
5.4.2 Interferometer Detection 207 5.5 Cantilever and Tip 209 5.6 SPM
System 211 5.7 Applications of SFM in Micro/Nano Measurements 212 5.7.1
Three-Dimensional (3D) Imaging 212 5.7.2 Micro/Nanoelectronics 215 5.7.3
Metrology 217 5.7.4 Manipulation and Spectroscopy 218 5.8 Conclusion 222
References 222 6 MEMS Online Measurements 227 6.1 Bulk Silicon
Micromachining 228 6.1.1 Principles 228 6.1.2 Location Platform 229 6.2
Surface Micromachining 235 6.2.1 Surface Sacrificial Layer Microfabrication
Process 236 6.2.2 Thermal Conductivity Measurements of Polysilicon Thin
Films 239 6.3 Polymer Materials Processing 245 6.3.1 Principles 245 6.3.2
Photosensitive Polyimide (PSPI) Microvalve 247 6.4 Conclusion 252
References 253 7 Typical Micro/Nanoscale Device Measurements 255 7.1 MEMS
Pressure Transducer Measurements 255 7.1.1 Introduction 255 7.1.2
Principles of MEMS Pressure Transducers 255 7.1.3 Electrical Property
Measurements 261 7.1.4 Static Testing of MEMS Pressure Sensors 267 7.1.5
Dynamic Measurements 271 7.1.6 Impact Factors of Pressure Sensor Testing
272 7.1.7 Reliability Measurements 273 7.2 MEMS Accelerator Measurements
276 7.2.1 Introduction 276 7.2.2 Low- and Medium-Range Accelerator
Measurements 277 7.2.3 High-g MEMS Accelerator Measurements 284 7.3 RF MEMS
Testing Technology 296 7.4 Micro/Nanoscale Devices for Infrared Measurement
304 7.4.1 Infrared Imaging System 305 7.4.2 Infrared Imaging Measurement
307 7.5 Typical NEMS Device Measurement 311 7.5.1 NEMS Accelerometer
Measurements 312 7.5.2 Working Principles of a NEMS Acoustic Sensor 318
References 325 Index 327
1.1.1 Development of MEMS 1 1.1.2 Development of NEMS 3 1.2 Development of
Micro/Nanoscale Measurements 5 1.2.1 Significance 5 1.2.2 Types of
Micro/Nanoscale Measurements 6 1.2.3 Conclusion and Outlook 7 References 9
2 Geometry Measurements at the Micro/Nanoscale 11 2.1 Microvision
Measurement 11 2.1.1 Micro/Nanoscale Plane Geometry Parameter Tests 11
2.1.2 Integrality Tests and Analysis of Micro/Nanometer Structures 12 2.1.3
Micro/Nanoscale Plane Dynamic Characteristic Tests 13 2.2 3D Morphology
Measurements in Contact Mode 15 2.2.1 Scanning Probe Microscopy 15 2.2.2
Near-Field Scan Optics Microscopy (NSOM) 21 2.2.3 Scanning Electron
Microscopy 26 2.2.4 Transmission Electron Microscopy 31 2.3 3D Morphology
Optics Measurements with Non-Contact Modes 36 2.3.1 Laser Scanning
Microscopy 37 2.3.2 White Light Interferometry Morphology Measurements 40
2.4 Micro/Nanoscale Tricoordinate Measurements 63 2.4.1 Basics 64 2.4.2
Experimental Techniques 67 2.5 Measurement of Film Thickness 71 References
77 3 Dynamic Measurements at the Micro/Nanoscale 79 3.1 Stroboscopic
Dynamic Vision Imaging 79 3.1.1 Principles of Plane Dynamic Measurements 80
3.1.2 Equipment 81 3.1.3 Block Matching and Phase Correlation Methods 84
3.1.4 Optical Flow Field Measurement Method 86 3.2 Stroboscopic Microscopy
Interference Measurements 90 3.2.1 Principles 90 3.2.2 Equipment 92 3.2.3
System 93 3.3 Laser Doppler Microscope Vibration Measurements 94 3.3.1
Differential Doppler Vibration Measurements 98 3.3.2 Laser Torsional
Vibration Measurements 99 3.3.3 Laser Doppler Vibration Measurements of
Single Torsional Vibrations and Single Bend Vibrations 100 3.3.4 Laser
Doppler Flutter Measurements 103 3.4 Conclusion 104 3.4.1 Mechanical
Processes in AFM 104 3.4.2 Measurement Theory and Methods of
Micro/Nanometer Mechanics in AFM 106 3.4.3 Micro/Nano Measurement System
and Reference Cantilever Measurement Method in AFM 112 3.4.4 Measurement of
Spring Constant of Cantilever and System Verification 115 3.4.5 Application
of AFM to Nanometrology 117 References 119 4 Mechanical Characteristics
Measurements 121 4.1 Residual Stress Measurements of Microstructures 122
4.1.1 Residual Stress 122 4.1.2 Measurements 122 4.2 Axial Tensile
Measurement 131 4.2.1 Traditional Tensile Method 131 4.2.2 Conversion
Tensile Method 136 4.2.3 Integrated Tensile Method 137 4.2.4 Displacement
Measurement of Uniaxial Tension 138 4.3 Nano-Indentation Measurements Using
Contact Dode 140 4.3.1 Basic Principles of Nano-Indentation Technology 140
4.3.2 Nano-Indentation Measurements 148 4.3.3 Features of Nano-Indentation
Technology 150 4.4 Bend Method 151 4.4.1 Principles 151 4.4.2
Micro/Nanobeams 154 4.4.3 Advantages and Disadvantages of the Bend Method
157 4.5 Resonance Method 157 4.5.1 Resonance Frequency 158 4.5.2 Intrinsic
Resonance Frequency 159 4.6 Stress Measurements Based on Raman Spectroscopy
160 4.6.1 Raman Scattering 160 4.6.2 Theory 161 4.6.3 Experimental
Techniques 162 4.6.4 System 164 4.6.5 Experiments 172 4.6.6 Conclusion and
Prospects 173 4.7 Bonding Strength Measurements 174 4.7.1 Principles 174
4.7.2 Crack Spread Method 183 References 189 5 SPM for MEMS/NEMS
Measurements 191 5.1 Introduction 191 5.2 Atomic Force Measurement 192
5.2.1 Atomic Force Measurement Methods 192 5.3 Instruments 199 5.3.1
Schematic of the AFM Unit 199 5.3.2 Fiber and Sample Approach Stages 200
5.3.3 Tube Scanner 202 5.3.4 Vibration Isolation System 204 5.4
Interferometer Detection Method 205 5.4.1 Optical Interference Theory 205
5.4.2 Interferometer Detection 207 5.5 Cantilever and Tip 209 5.6 SPM
System 211 5.7 Applications of SFM in Micro/Nano Measurements 212 5.7.1
Three-Dimensional (3D) Imaging 212 5.7.2 Micro/Nanoelectronics 215 5.7.3
Metrology 217 5.7.4 Manipulation and Spectroscopy 218 5.8 Conclusion 222
References 222 6 MEMS Online Measurements 227 6.1 Bulk Silicon
Micromachining 228 6.1.1 Principles 228 6.1.2 Location Platform 229 6.2
Surface Micromachining 235 6.2.1 Surface Sacrificial Layer Microfabrication
Process 236 6.2.2 Thermal Conductivity Measurements of Polysilicon Thin
Films 239 6.3 Polymer Materials Processing 245 6.3.1 Principles 245 6.3.2
Photosensitive Polyimide (PSPI) Microvalve 247 6.4 Conclusion 252
References 253 7 Typical Micro/Nanoscale Device Measurements 255 7.1 MEMS
Pressure Transducer Measurements 255 7.1.1 Introduction 255 7.1.2
Principles of MEMS Pressure Transducers 255 7.1.3 Electrical Property
Measurements 261 7.1.4 Static Testing of MEMS Pressure Sensors 267 7.1.5
Dynamic Measurements 271 7.1.6 Impact Factors of Pressure Sensor Testing
272 7.1.7 Reliability Measurements 273 7.2 MEMS Accelerator Measurements
276 7.2.1 Introduction 276 7.2.2 Low- and Medium-Range Accelerator
Measurements 277 7.2.3 High-g MEMS Accelerator Measurements 284 7.3 RF MEMS
Testing Technology 296 7.4 Micro/Nanoscale Devices for Infrared Measurement
304 7.4.1 Infrared Imaging System 305 7.4.2 Infrared Imaging Measurement
307 7.5 Typical NEMS Device Measurement 311 7.5.1 NEMS Accelerometer
Measurements 312 7.5.2 Working Principles of a NEMS Acoustic Sensor 318
References 325 Index 327