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Lecture
Superconducting Electronics: Materials Perspective
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Quantum Computing Basics
Covers the basics of quantum computing, focusing on superconducting qubits, scaling challenges, and potential applications.
Josephson Junction Fabrication
Details the fabrication process of Josephson junctions, highlighting reliability and identical characteristics for quantum computation applications.
Josephson effect
Explains the Josephson effect and the significance of the Josephson Junction in superconducting technology.
Superconducting Shielding: Design and Properties
Explores superconducting shielding, the Meissner effect, macroscopic wave function, and single-spin detection in biological research.
Proximitized Materials: From Spintronics to Majorana States
Explores the transition from spintronics to Majorana states in proximitized materials, focusing on magnetic proximity and topological superconductivity detection.
Transmon Qubit: Anharmonicity and Coupling Strategies
Explores energy levels of CPB and transmon qubit, anharmonicity, and coupling strategies for quantum computing.
Quantum State Spaces: Pure vs Mixed States
Explores quantum state spaces, comparing pure and mixed states, and discusses ensemble decompositions.
Quantum and Nanocomputing: Qubit Realization & Control
Covers the design, control, and readout of superconducting qubits.
Superconducting Qubits: Non-Demolition Measurements and Control Techniques
Covers superconducting qubits, focusing on non-demolition measurements and control techniques essential for quantum computing.
Gauge Invariance: Electromagnetic Potentials
Explores gauge invariance, electromagnetic potentials, superfluid velocity, and superconductors' magnetic field expulsion.
