Lectures related to Lorentz Invariance: Velocities, Time Dilation, Length Contraction

Lorentz Transformations: Symmetries and Boosts

Explores Lorentz transformations, boosts, and symmetries in Newtonian mechanics.

Covers EM Field and Discrete Symmetries, emphasizing the importance of symmetries in quantum field theory.

Covers the Lie algebra of the Lorentz group, focusing on boosts, rotations, and transformations.

Relativity: Special Relativity Principles and Consequences

Explains the principles of special relativity, including time dilation, length contraction, and the Lorentz transformations.

Lorentz Transformations and Covariant Tensors

Explores Lorentz transformations, covariant tensors, rotational invariance, and linear transformations in vector spaces.

Symmetries and Groups in Quantum Mechanics

Covers the role of symmetries and groups in quantum mechanics, focusing on SU2 and SU3, their properties, and implications for physical theories.

Quantum Field Theory: Poincaré Group

Explores Einsteinian relativity, the Lorentz group, and Poincaré transformations, emphasizing proper and non-orthochronous components.

Symmetries in Mechanics and Wave Equations

Explores symmetries in Newtonian mechanics and wave equations, highlighting their significance in understanding physical laws.

Special and General Relativity

Introduces special and general relativity, Einstein equations, and gravitational dynamics.

Spinorial Fields: Lorentz Group Representation

Covers the most general representation of Lorentz group on spinorial fields.

Symmetries of the Wave Equation

Explores the symmetries of the wave equation and Lorentz boosts in relation to Galilean boosts.

Symmetries of the Wave Equation

Explores the symmetries of the wave equation under Lorentz transformations and the Poincare group.

Tensors and Lorentz Transformations

Covers tensors, Lorentz transformations, and electrodynamics in relativistic notation.

Discrete Symmetries: Asymptotic States and S-matrix

Covers the concept of discrete symmetries, focusing on the introduction to asymptotic states and S-matrix.

Relativity Concepts: Understanding Lorentz Transformations

Covers the fundamental concepts of relativity, focusing on Lorentz transformations and their applications in measuring time and length in different reference frames.

Time Dilation and Lorentz Contraction

Explores time dilation, Lorentz contraction, and isotropy in physics.

Relativity and Thermodynamics: Key Concepts Explained

Covers key concepts in relativity and thermodynamics, including time dilation, length contraction, and the principles of heat engines.

Symmetries of Navier-Stokes Equations

Explores the symmetries of Navier-Stokes equations in periodic boxes, including translations, transformations, rotations, and scaling.

Quantum Theory: Lorentz Transformation

Explores the Lorentz transformation in Quantum Theory, emphasizing Fock space representation and momentum concepts.

Special Relativity: Lorentz Transformations

Explores special relativity, Lorentz transformations, time dilation, and the constancy of the speed of light.