ISBN-10:
1848216696
ISBN-13:
9781848216693
Pub. Date:
06/29/2015
Publisher:
Wiley
Nanoelectromechanical Systems / Edition 1

Nanoelectromechanical Systems / Edition 1

by Laurent Duraffourg, Julien Arcamone
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Product Details

ISBN-13: 9781848216693
Publisher: Wiley
Publication date: 06/29/2015
Series: ISTE Series
Pages: 212
Product dimensions: 6.40(w) x 9.30(h) x 0.70(d)

About the Author

Laurent DURAFFOURG is Staff Scientist at the CEA/LETI-Minatec laboratories in Grenoble, France.

Julien ARCAMONE is a Business Developer MEMS at CEA-LETI in Grenoble, France.

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Table of Contents

PREFACE vii

PHYSICAL CONSTANTS ix

NOTATIONS xi

CHAPTER 1. FROM MEMS TO NEMS 1

1.1. Micro- and nanoelectromechanical systems: an overview 1

1.2. Conclusion 9

CHAPTER 2. TRANSDUCTION ON THE NANOMETRIC SCALE AND THE NOTION OF NOISE 13

2.1. Mechanical transfer function 14

2.2. Transduction principles 20

2.2.1. The actuation of nanostructures 23

2.2.2. Detection 31

2.3. Self-oscillation and noises 49

2.4. Conclusion 58

CHAPTER 3. MONOLITHIC INTEGRATION OF NEMS WITH THEIR READOUT ELECTRONICS 61

3.1. Foreword 61

3.1.1. Why integrate NEMS with their readout electronics? 61

3.1.2. What are the differences between MEMS-CMOS and NEMS-CMOS? 62

3.2. The advantages of and main approaches to monolithic integration 64

3.2.1. A comparison of integration schemes and their electrical performance 64

3.2.2. Closed-loop NEMS-CMOS oscillators: the essential building block for NEMS-based frequency sensors 69

3.2.3. Overview of the main achievements from the perspective of manufacturing technology 70

3.3. Analysis of some significant achievements from the perspective of transduction 75

3.3.1. Examples of capacitive NEMS-CMOS 75

3.3.2. Examples of piezoresistive NEMS-CMOS 82

3.3.3. Alternative approaches 85

3.4. Conclusions and future perspectives 86

CHAPTER 4. NEMS AND SCALING EFFECTS 89

4.1. Introduction 89

4.1.1. Intrinsic losses 96

4.1.2. Extrinsic losses 97

4.2. Near field effect in a nanostructure: Casimir force 102

4.2.1. Intuitive explanation of the Casimir force 102

4.2.2. The problem 105

4.2.3. Rigorous calculation of the Casimir force between two silicon slabs 107

4.2.4. Impact of the Casimir force in a nano-accelerometer 113

4.2.5. Conclusion 117

4.3. Example of “intrinsic” scaling effects: electrical conduction laws 117

4.3.1. Electrical resistivity 117

4.3.2. Piezoresistive effect 125

4.4. Optomechanical nano-oscillators and quantum optomechanics 136

4.5. Conclusion 147

CHAPTER 5. CONCLUSION AND APPLICATION PROSPECTS: FROM FUNDAMENTAL PHYSICS TO APPLIED PHYSICS 149

APPENDIX 167

BIBLIOGRAPHY 175

INDEX 193

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