Lecture

Quantum Physics I

Related lectures (32)

Covers the basics of quantum physics, including the Stern-Gerlach experiment and classical magnetic moments.

Explores the measurement of magnetic moments in silver atoms and delves into quantum mechanics concepts like spin quantization and superposition.

Quantum Information: Magnetic Moments and Spin

Explores quantum information on magnetic moments, spin, observable properties, and photon polarization, emphasizing matrices' role in quantum measurements.

Quantum Information: Spin and Magnetic Moments

Explores the concept of spin in quantum information and its relation to magnetic moments and particle spins.

Magnetic Moments and Spin

Explores magnetic moments, spin, and quantum descriptions using Pauli matrices and Stern-Gerlach experiments.

Exchange Interaction: Understanding Magnetic Properties

Covers exchange interaction's role in ferromagnetism and its dependence on interatomic distances and Coulomb forces.

Heisenberg Interaction: 2-Qubit Gates

Explores Heisenberg interaction and 2-qubit gates in quantum systems with intrinsic magnetic moments and Pauli matrices.

Double Slit Experiment and Quantum Information Processing

Explores the historical development of quantum mechanics and information theory, focusing on the double slit experiment and quantum phenomena.

Quantum Mechanics: Bohr Model and Energy Quantization

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

Quantum Description of Pulsed NMR

Explores the quantum principles behind Pulsed NMR Spectroscopy, including Zeeman interaction and spin manipulation through radiofrequency irradiation.

Magnetic Moments and Spin

Covers the quantum description of magnetic moments and spin, including the Pauli matrices and observable energy.

Introduction to Quantum Sensing

Introduces quantum sensing and metrology, exploring precision limitations and unified frameworks for analysis with elementary quantum systems.

The Dirac equation and spin

Explores the interpretation of energy degeneracy, non-commutativity, spin operators, helicity, and discrete symmetries in the Dirac equation.

Magnetic Resonance: Spin Qubits and Their Applications

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

The Spin: Quantum Numbers, Electron's Rotation, and Magnetic Moment

Explores quantum numbers, electron's spin, magnetic moment, and the necessity of relativity in quantum physics.

Quantum Physics I

Explores discrete and continuous degrees of freedom, canonical commutation relations, and the correspondence between classical and quantum mechanics.

Electron Configurations and Quantum Physics

Explores electron configurations, quantum numbers, and the implications of electron spin.

Hamiltonian of Heisenberg: Interaction and Energy Levels

Covers the Hamiltonian of Heisenberg and the interaction between classical magnetic moments.

Basis of Nuclear Magnetization

Explores the classical and quantum-mechanical basis of nuclear magnetization and the quantization of angular momentum and energy levels.

Time-Independent Perturbation Theory: Degenerate Case

Explores time-independent perturbation theory in the degenerate case within quantum physics.