Introduction to electrostatics: Electric charge, Coulomb's law, concept of electrostatic field and potential, charge motion in electric field. Gauss law and applications. Electric potential, electric potential difference, electric dipole, electric potential energy, determination of electrostatic field from measurements of potential. Electrical properties of matter: Dielectric and conductors. Biot-Savart Law . Magnetic induction, magnetic flux, magnetic dipole field,scalar magnetic potential, magnetized material fields, magnetization, magnetic field equations, hysteresis diamagnitism, paramagnetism, ferromagnetism, antiferroromagnitism, Ampere's Law,current carrying conductors, solenoid. Induction currents, time-varying magnetic flux, Faraday's Law, Lenz's Law , inductance coefficient L, LR Circuit. Energy in electric and magnetic fields, electromagnetic oscillations in LC system, dumped and forced oscillations, resonance in LCR circuit. Wave concepts, principle of electromagnetic wave generation, e-m field energy and intensity , electric dipole, polarization, dielectrics. Poynting Vector, inductive magnetic fields, displacement current, Maxwell equations , EM wave propagation in vacuum and in matter, EM spectrum range, transmission lines, waveguides, interaction of EM waves with matter: absorption, scattering, reflection, interference diffraction, photoelectric effect.

Fundamental concepts of fluids, properties-definitions, hydrostatics, buoyancy-floating-balance, fluid kinematics-basic equations, application of mass, energy, momentum and torque balance. Real fluids (viscous flows, Reynolds number, boundary layers, drag, Stokes law, flow in single pipes, mechanical lubrication). Ideal flow (velocity potential, stream functions).

This course is an introduction to the relationships connecting atomic structure and macroscopic properties of solids. It includes an introduction to the calculus of periodic functions of three variables, including Bravais Lattices. Two simple models are used throughout the class: the homogeneous solid (Jellium) and the linear combination of atomic orbitals (LCAO). Through these models, all key properties of solids are introduced to the students, including mechanical, thermal, electrical, optical and magnetic properties. Relatioships between quantities that describe different properties are highlighted.