Module 2 Lecture 3 covers wave phenomena, particularly the wave equation, and explores its applications in various physical contexts like acoustics and optics.
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Module 1 Lecture 1 introduces students to the foundational concepts of electricity and magnetism. It covers the basic principles and mathematical approaches necessary for understanding electrostatic interactions.
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Module 1 Lecture 2 continues to build on the principles of electrostatics, delving deeper into electric fields and their mathematical formulations.
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Module 1 Lecture 3 explores electrostatic energy and macroscopic fields, emphasizing the interactions of charges and their cumulative effects in different mediums.
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Module 1 Lecture 4 addresses the properties of conductors and dielectrics, highlighting their roles in electric fields and practical applications in technology.
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Module 2 Lecture 1 dives into the motion of steady currents, exploring the dynamics of electric charge flow in conductive materials and the factors influencing this movement.
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Module 2 Lecture 2 investigates the effects of currents on magnetic fields, introducing students to the interaction of electricity and magnetism through practical examples.
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Module 2 Lecture 3 covers wave phenomena, particularly the wave equation, and explores its applications in various physical contexts like acoustics and optics.
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Module 2 Lecture 4 delves into interference experiments, showcasing their importance in understanding wave behavior and the principles of superposition.
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Module 2 Lecture 5 wraps up the course by integrating previous concepts and exploring advanced topics in electricity and magnetism, preparing students for further studies.
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