Lectures related to Quantum Wells: Energy Levels and Quantum States

Quantum Wells: Coupled Quantum States and Energy Levels

Covers quantum wells, coupled states, energy levels, and the implications for molecular formation.

Quantum Mechanics: Harmonic Oscillator and Molecular Interactions

Discusses the harmonic oscillator in quantum mechanics and its implications for molecular interactions and energy levels.

Quantum Wells: Understanding Potential and Wave Functions

Discusses quantum wells, potential steps, tunneling effects, and their applications in quantum mechanics and electronic devices.

Quantum Computing Basics

Covers the basics of quantum computing, focusing on superconducting qubits, scaling challenges, and potential applications.

Superconducting Qubits: Principles and Applications

Covers the principles and applications of superconducting qubits in quantum science.

Quantum Mechanics: Bohr Model and Energy Quantization

Discusses the Bohr model of the atom, focusing on electron orbits and energy quantization.

Spin Qubits: Quantum Point Contacts and Measurements

Covers the principles of spin qubits and their measurement techniques using quantum point contacts.

Quantum Measurement Operators: Concepts and Examples

Covers quantum measurement operators, their definitions, applications, and examples in quantum mechanics.

Superconducting Qubits: Non-Demolition Measurements and Control Techniques

Covers superconducting qubits, focusing on non-demolition measurements and control techniques essential for quantum computing.

Quantum Propagation: Hamiltonian and State Decomposition

Discusses quantum propagation, focusing on Hamiltonians, eigenstates, and their time evolution in quantum mechanics.

Quantum Physics: Harmonic Oscillator and Hydrogen Atom

Explores harmonic oscillators, infinite wells, and the hydrogen atom's quantum physics.

Quantum Principles: Atoms and Molecules

Covers the application of quantum principles to the behavior of atoms and molecules, focusing on energy levels and molecular formation.

Principles of Quantum Mechanics: Wave-Particle Dualism

Explores the wave-particle dualism in quantum mechanics and the quantification of energy levels in atoms.

Classical and Quantum Mechanics: Foundations and Applications

Explores classical and quantum mechanics, covering observables, momentum, Hamiltonian, and the Schrödinger equation, as well as quantum chemistry and the Schrödinger's cat experiment.

Quantum Random Number Generation

Explores quantum random number generation, discussing the challenges and implementations of generating good randomness using quantum devices.

Quantum Qubits: Understanding the Basics

Covers the basics of quantum qubits, including abstract qubits, states, measurement, and evolution in quantum computation.

Polarisation of Photons

Explores photon polarisation, including linear, circular, and elliptical polarisation concepts.

Magnetic Resonance: Spin Qubits and Their Applications

Covers magnetic resonance principles and their application to spin qubits in quantum science.

Qubits: Tensor Products and Entangled States

Explains tensor products and entangled states in quantum mechanics, focusing on pairs of qubits and their mathematical representations.

Qubits: Understanding Quantum States and Operations

Covers the fundamentals of qubits, including their states, superposition, and operations in quantum mechanics.