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The International System of Units, the SI, provides the foundation for all measurements in science, engineering, economics, and society. The SI has been fundamentally revised in 2019. The new SI is a universal and highly stable unit system based on invariable constants of nature. Its implementation rests on quantum metrology and quantum standards, which base measurements on the manipulation and counting of single quantum objects, such as electrons, photons, ions, and flux quanta. This book explains and illustrates the new SI, its impact on measurements, and the quantum metrology and quantum technology behind it. The book is based on the book ?Quantum Metrology: Foundation of Units and Measurements? by the same authors. From the contents: -Measurement -The SI (Système International d?Unités) -Realization of the SI Second: Thermal Beam Cs Clock, Laser Cooling, and the Cs Fountain Clock -Flux Quanta, Josephson Effect, and the SI Volt -Quantum Hall Effect, the SI Ohm, and the SI Farad -Single-Charge Transfer Devices and the SI Ampere -The SI Kilogram, the Mole, and the Planck constant -The SI Kelvin and the Boltzmann Constant -Beyond the present SI: Optical Clocks and Quantum Radiometry -Outlook
Auteur
Ernst O. Gobel was president of the Physikalisch-Technische Bundesanstalt (PTB), the German national metrology institute from 1995 until the end of 2011. After his PhD from the University of Stuttgart, Germany, and a postdoctoral stay at Bell Laboratories in Holmdel, USA, he continued his scientific career at Stuttgart University, and subsequently at the Max-Planck-Institut for Solid State Physics in Stuttgart. In 1985 he was appointed full professor at the University of Marburg, Germany. He received several scientific awards such as the Leibniz Prize of the German Research Foundation (DFG) and the Max Born Award jointly provided by the Institute of Physics (London) and the German Physical Society (DPG).
Uwe Siegner is Head of the Division "Electricity" at the PTB since 2009, and lecturer at the Technical University of Braunschweig, Germany. He obtained his PhD from the University of Marburg after which he spent two years as postdoctoral researcher at the Lawrence Berkeley National Laboratory, USA. He did his habilitation at the ETH Zurich, Switzerland, and accepted a position at the PTB in 1999.
Contenu
Foreword ix
Preface xi
List of Abbreviations xv
1 Introduction 1
References 3
2 Some Basics 5
2.1 Measurement 5
2.1.1 Limitations of Measurement Uncertainty 5
2.1.1.1 The Fundamental Quantum Limit 6
2.1.1.2 Noise 7
2.2 The SI (Système International d'Unités) 9
2.2.1 The Second: Unit of Time 11
2.2.2 The Meter: Unit of Length 13
2.2.3 The Kilogram: Unit of Mass 14
2.2.4 The Ampere: Unit of Electric Current 15
2.2.5 The Kelvin: Unit of Thermodynamic Temperature 16
2.2.6 The Mole: Unit of Amount of Substance 18
2.2.7 The Candela: Unit of Luminous Intensity 19
2.2.8 Summary: Base and Derived Units of the SI 21
References 21
3 Realization of the SI Second: Thermal Beam Cs Clock, Laser Cooling, and the Cs Fountain Clock 23
3.1 The Thermal Beam Cs Clock 25
3.2 Techniques for Laser Cooling and Trapping of Atoms 28
3.2.1 Doppler Cooling, Optical Molasses, and Magneto-Optical Traps 29
3.2.2 Cooling Below the Doppler Limit 31
3.3 The Cs Fountain Clock 32
References 35
4 Flux Quanta, Josephson Effect, and the SI Volt 39
4.1 Josephson Effect and Quantum Voltage Standards 39
4.1.1 Basics of Superconductivity 39
4.1.2 Basics of the Josephson Effect 41
4.1.2.1 AC and DC Josephson Effect 42
4.1.2.2 Mixed DC and AC Voltages: Shapiro Steps 43
4.1.3 Basic Physics of Real Josephson Junctions 44
4.1.4 Josephson Voltage Standards 46
4.1.4.1 General Overview: Materials and Technology of Josephson Arrays 47
4.1.4.2 SIS Josephson Voltage Standards 48
4.1.4.3 Programmable Binary Josephson Voltage Standards 50
4.1.4.4 Pulse-Driven AC Josephson Voltage Standards 53
4.1.5 Metrology with Josephson Voltage Standards 57
4.1.5.1 DC Voltage, the SI Volt 57
4.1.5.2 The Conventional Volt in the Previous SI 59
4.1.5.3 AC Measurements with Josephson Voltage Standards 59
4.2 Flux Quanta and SQUIDs 62
4.2.1 Superconductors in External Magnetic Fields 62
4.2.1.1 MeissnerOchsenfeld Effect 63
4.2.1.2 Flux Quantization in Superconducting Rings 65
4.2.1.3 Josephson Junctions in External Magnetic Fields and Quantum Interference 66
4.2.2 Basics of SQUIDs 67
4.2.3 Applications of SQUIDs in Measurement 71
4.2.3.1 Real DC SQUIDs 71
4.2.3.2 SQUID Magnetometers and Magnetic Property Measurement Systems 73
4.2.3.3 Cryogenic Current Comparators: Current and Resistance Ratios 74
4.2.3.4 Biomagnetic Measurements 76
4.3 Traceable Magnetic Flux Density Measurements 77
References 80
5 Quantum Hall Effect, the SI Ohm, and the SI Farad 87
5.1 Basic Physics of Three- and Two-Dimensional Semiconductors 88
5.1.1 Three-Dimensional Semiconductors 88
5.1.2 Two-Dimensional Semiconductors 90
5.2 Two-Dimensional Electron Systems in Real Semiconductors 91
5.2.1 Basic Properties of Semiconductor Heterostructures 92
5.2.2 Epitaxial Growth of Semiconductor Heterostructures 93
5.2.3 Semiconductor Quantum Wells 94
5.2.4 Modulation Doping 95
5.3 The Hall Effect 97
5.3.1 The Classical Hall Effect 97
5.3.1.1 The Classical Hall Effect in Three Dimensions 97
5.3.1.2 The Classical Hall Effect in Two Dimensions 98
5.3.2 Physics of the Quantum Hall Effect 99
5.4 Metrology Using the Quantum Hall Effect 103
5.4.1 DC Quantum Hall Resistance Standards, the SI Ohm 103
5.4.2 The Conventional Ohm in the Previous SI 104
5.4.3 Technology of DC Quantum Hall Resistance Standards and Resistance Scaling 106
5.4.4 AC Quantum Hall Resistance Standards, the SI Farad 108 5.4.5 Relation Between Electrical Metrol...