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Microwave Techniques in Superconducting Quantum Computers

✍ Scribed by Alan Salari

Publisher
Artech House
Year
2024
Tongue
English
Leaves
386
Category
Library
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✦ Synopsis

The first of its kind, Microwave Techniques in Superconducting Quantum Computers introduces microwave and quantum engineers to essential practical techniques and theoretical foundations crucial for operating and implementing hardware in superconducting quantum processors. This practical resource covers an extensive range of topics, including Introduction to Quantum Physics, Introduction to Quantum Computing, Superconducting Qubits, Microwave Systems, Microwave Components, Principles of Electromagnetic Compatibility, Control Hardware for Superconducting Qubits, and Principles of Cryogenics. A wide range of principles and techniques discussed in the book can be applied to other semiconductor qubits, such as spin and topological qubits. Such technical knowledge equips the reader with essential skills to succeed in the demanding industries and research settings surrounding quantum technologies. With clearly outlined learning objectives and coherent explanations of intricate concepts, this is a must-have reference for a wide spectrum of professionals, including microwave and quantum engineers, technical managers, technical sales engineers in quantum computing and microwave companies, as well as newcomers entering this field.

✦ Table of Contents

Microwave Techniques in Superconducting
Quantum Computers
Contents
Foreword
Preface
Acknowledgments
Chapter 1
Introduction to Quantum Physics
1.1 A Brief History of Quantum Mechanics
1.2 Quantum Versus Classical Mechanics
1.3 Schrödinger Equation
1.4 The Machinery of Quantum Calculations
1.5 Solving the Schrödinger Equation
1.5.1 Time-Independent Schrödinger Equation
1.5.2 Standard Hamiltonians
1.6 Quantum Measurement
1.6.1 Collapse of the Wave Function
1.6.2 Expectation Value
1.6.3 Variance or Uncertainty
1.6.4 Uncertainty Principle
1.6.5 Heisenberg’s Picture
1.6.6 Quantum Coherence
1.7 Quantum Entanglement
References
Chapter 2
Introduction to Quantum Computing
2.1 Quantum Computing
2.1.1 The Power of Quantum Computing
2.1.2 DiVincenzo Criteria
2.1.3 Applications of a Quantum Computer
2.2 Quantum Information Processing
2.2.1 Single-Qubit Gates
2.2.2 Two-Qubit Gates
2.2.3 Gate Fidelity
2.2.4 Quantum Circuits
2.2.5 Quantum Algorithm
2.2.6 Quantum Error Correction
2.2.7 Quantum Supremacy
2.3 Quantum Computing Platforms
2.3.1 Ions
2.3.2 Neutral Atoms
2.3.3 Semiconductor Qubits
2.4 Challenges and Opportunities in Quantum Computing
2.4.1 Technical Challenges of Scaling
2.4.2 Skillsets for Quantum Hardware Engineers
References
Chapter 3
Superconducting Qubits
3.1 Introduction to Superconductivity
3.1.1 Cooper Pairs
3.1.2 Types of Superconductors
3.1.3 Josephson Junction
3.2 Superconducting Qubit
3.2.1 Artificial Atom
3.2.2 Cooper Pair Box
3.2.3 Transmon Qubit
3.2.4 Qubit Coherence Time Scales
3.3 Qubit Control and Readout
3.3.1 Qubit Control
3.3.2 Qubit Readout
3.3.3 Spectroscopic Measurement Methods
3.3.4 Equivalent Circuit of Qubit-Cavity Coupling
3.3.5 Qubit Control and Readout in Practice
3.4 Two-Qubit System
3.4.1 Dispersive Two-Qubit Interactions
3.5 Calibration of Single-Qubit Operations
3.6 Testing the Performance of a Quantum Processor
References
Chapter 4
Microwave Systems
4.1 A Brief History of Microwave Engineering
4.2 Microwave Engineering
4.3 Microwave System Analysis
4.3.1 Microwave Link
4.3.2 Signal Degradation Factors
4.3.3 Nonlinear Effects in Microwave Systems
4.3.4 Dynamic Range
4.3.5 Error Vector Magnitude
References
Chapter 5
Microwave Components
5.1 Microwave Component Analysis
5.1.1 Tools for the Analysis of Microwave Components
5.2 Signal Generation
5.3 Signal Transmission
5.3.1 TEM-Mode Transmission Lines
5.3.2 Non-TEM Transmission Lines
5.3.3 Types of Transmission Lines
5.3.4 Microwave Connectors
5.4 Signal Processing
5.4.1 Performance Specifications of Microwave Components
5.4.2 Amplitude Manipulation
5.4.3 Frequency Manipulation
5.4.4 Phase Manipulation
5.5 Signal Detection
5.5.1 Homodyne Detection
5.5.2 Superheterodyne Detection
5.5.3 Direct RF Sampling
References
Chapter 6
Principles of Electromagnetic Compatibility
6.1 Signal Integrity
6.2 EMC
6.2.1 Interaction of an Electronic System with the Environment
6.2.2 Interference Sources
6.2.3 Crosstalk
6.3 Electromagnetic Shielding
6.1 Shielding Effectiveness
6.3.2 Effect of Penetration in the Shield
6.3.3 Effect of Grounding on the Shield
6.3.4 Shielding Techniques for Qubits
6.4 Filtering
6.5 Grounding
6.5.1 Grounding of Wires
References
Chapter 7
Control Hardware for Superconducting Qubits
7.1 High-Level Description of the Setup
7.2 Low-Level Description of the Setup
7.3 Room-Temperature Setup
7.3.1 Signal Generation
7.3.2 Signal Processing
7.3.3 Further Considerations at Room Temperature
7.4 Cryogenic Setup
7.4.1 DC Wiring
7.4.2 Heat Loads
7.4.3 Noise-Suppression Techniques
7.4.4 Signal Amplification
7.4.5 Further Considerations for the Cryogenic Setup
7.4.6 Vibrational Damping and Decoupling
7.5 Future Directions for the Control Hardware
7.5.1 Integrated Hardware
7.5.2 Cryogenic CMOS Chips
7.6 Automation and Control of the Experiment
References
Chapter 8
Principles of Cryogenics
8.1 Introduction
8.2 An Overview of Cooling Techniques
8.3 Cryogens
8.3.1 Cooling Mechanisms
8.3.2 Storage and Transportation of Cryogens
8.4 Mechanical Refrigerators
8.5 Pumped-Helium Refrigerators
8.6 Dilution Refrigerator
8.6.1 Principle of Dilution Refrigeration
8.6.2 Components of a Dilution Refrigerator
8.6.3 Dry and Wet Dilution Fridge
8.7 Cryogenic Thermometry
8.7.1 Cryogenic Temperature Measurements
8.7.2 Installation Considerations
8.8 Materials in Cryogenic Environments
References
About the Author
Index

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