Lectures related to General Physics: Fluids and Electromagnetism

Magnetostatics: Magnetic Field and Force

Covers magnetic fields, Ampère's law, and magnetic dipoles with examples and illustrations.

Vector Calculus Review: Maxwell Equations

Covers a review of vector calculus and the Maxwell equations in electromagnetism.

Covers electrostatics, Coulomb force, and image charge method in electromagnetism.

Vector Analysis: Basics and Applications

Explores the importance of vector analysis in physics and engineering, showcasing its application in various laws and relationships.

Curl of Vector Field and Path Integrals

Explores the curl of a vector field and the calculation of path integrals in Cartesian coordinates.

Fluids and Electromagnetism

Explores closed and non-closed surfaces, divergence theorem, Stokes theorem, and fluid properties in fluid dynamics and electromagnetism.

Understanding Displacement Vector and Plane Waves

Explores the displacement vector D, plane waves, and magnetic vector potential, addressing student questions and clarifying key concepts.

Electrodynamics: Coupling and Maxwell's Equations

Explores the coupling between electric and magnetic fields and Maxwell's equations in electrodynamics.

Maxwell's Equations and Induction Phenomenon

Explores Maxwell's equations, induction in moving conductors, electromotive force, and electrical fields.

Vector Analysis: Gradient, Divergence, Curl

Covers the fundamental concepts of vector analysis, including the gradient, divergence, and curl operators.

Electromagnetic Phenomena

Introduces the importance of studying electromagnetic phenomena and Maxwell's equations.

Cosmological Puzzles: Dark Matter and Energy

Explores fundamental cosmological puzzles related to dark matter and energy.

Maxwell's Equations: Basics

Covers the basics of Maxwell's equations, describing the behavior of electric and magnetic fields.

Lorentz Covariant Formulation: Maxwell Equations

Covers Lorentz transformations, Maxwell equations, and charge conservation in Lorentz invariant physics.

Maxwell's Equations and Induction Law

Explores Maxwell's equations, magnetic flux, induction law, and induced currents.

Electromagnetism: UNIL-208

Introduces the basics of electromagnetism, covering derivatives, vector calculus, scalar and vector products, and their applications in physics and engineering.

Electromagnetic Waves in Plasmas

Covers the behavior of electromagnetic waves in non-magnetized plasmas and the simplification of equations for non-collisional plasmas.

Versatile EM Wave Description

Summarizes EM chapters, emphasizing wave description, reflection laws, and light intensity calculations.

Vector Fields and Lorentz Tensors: Representation Theory

Covers the transformation properties of vector fields and their representation in Lorentz tensors.

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