Quantum and Nanocomputing

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Related lectures (30)

Page 1 of 3

Covers quantum and nanocomputing, focusing on molecules as conductive elements, molecular transistors, and field coupling elements.

Quantum and Nanocomputing: Molecular Energy Spectrum and Conduction Mechanisms

Explores molecular energy spectrum analysis, conduction mechanisms in quantum dots, and transmission spectrum in molecular systems.

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Solid State Physics II: Tight-binding Model

Covers the tight-binding model for 1D atomic chains and its impact on energy levels.

Hybrid superconducting / quantum dot circuits

Covers hybrid cavity quantum electrodynamics with quantum dots and Josephson junction arrays, focusing on spin qubits and superconducting qubits.

Band Structure: Energy Levels and Fermi Sphere

Explains energy levels, Fermi sphere, and periodic potentials in different dimensions.

Electrochemistry Fundamentals

Covers the fundamentals of electrochemistry, focusing on cell potential, current production, and the relationship between current and reactant conversion.

Germanium Quantum Technology

Delves into the use of germanium in quantum computing, emphasizing hole-based quantum systems and materials advancements.

Quantum Bound States

Explores quantum bound states, energy levels, and superposition in molecular bonding.

Quantum Dots: Basic Concepts and Applications

Covers the concept of quantum dots, their similarities to atoms, and potential applications in quantum computation.