GENERAL PHYSICS II

Academic Year 2020/2021 - 2° Year
Teaching Staff: Sebastiano Francesco ALBERGO and Ivano LOMBARDO
Credit Value: 15
Scientific field: FIS/01 - Experimental physics
Taught classes: 84 hours
Exercise: 45 hours
Term / Semester: One-year

Learning Objectives

The course of General Physics II aims to study the laws of electromagnetism and optics synthesized in Maxwell's equations. The foundations of the theory of special relativity are introduced and the close connection with electromagnetism emphasized. The first elements of the classical (ie non-quantum) theory of radiation are also treated.

 

The approach to the description of the phenomena covered by the course will be experimental and / or phenomenological. Physical theories will be presented in terms of logical, mathematical and experimental evidence.

At the end of the course, the student will acquire inductive and deductive reasoning skills; will be able to schematize a phenomenon in terms of physical quantities; will be able to critically address the topics studied; will be able to set up a problem and solve iit, taking care of both the mathematical and physical aspects. Furthermore, he will be able to expose any subject of electromagnetism, optics or special relativity with appropriate language, focusing on the inductive / deductive process that allows to reach conclusions from the starting hypotheses.


Course Structure

Lessons: 12 credits;

Exercise: 3 credits

Should the circumstances require online or blended teaching, appropriate
modifications to what is hereby stated may be introduced, in order to
achieve the main objectives of the course.


Detailed Course Content

1 – Electrostatics in vacuum and in conductors

Coulomb’s law. The electric field. Continuous charge distribution. Field lines., flux, Gauss law. Divergence of electric field. Divergence theorem. Applications of Gauss’s law. The circulation of electric Field. Curl and Stokes’s theorem. Work and energy in electrostatics. Electric potential. The potential of a localized charge distribution. Energy of a point charge distribution. Energy of a continuous charge distribution. Energy of electric field. Conductors: basic properties. Conductors in electric fields. Induced charges. Surface charge density. Poisson equation and Laplace equation. Laplace equation solutions. Harmonic functions. Boundary conditions and uniqueness theorem. Method of variable separation in cartesian and spherical coordinates. Poisson’s equation solutions. Method of image charges. Induction and potential coefficients. Conductor capacity. Capacitors. Energy in capacitors. Forces between capacitor plates. Electrostatic pressure. Conductor systems. Electric Dipole. Large distance potential. Forces and momenta on dipoles. The multipole expansion of electric potential.

 

 

2- Electrostatics in dielectrics

 

Dielectrics. Induced dipoles. Alignment of polar molecules. Polarization. Linear dielectrics. Susceptibility. Permittivity. Dielectric constant. Bound charges. Physical interpretation of bound charges. Electric field inside a dielectrics. Gauss’s law in the presence of dielectrics. Electric Displacement D. Electrostatic problem in the presence of dielectrics. Boundary conditions. Boundary value problems with linear dielectrics. Energy in dielectric systems. Dielectric rigidity.

 

 

3 - Electric currents

 

Electric current and current density. Charge conservation and continuity equation. Stationary currents. Electric conductivity and Ohm law. Resistivity. Resistance and resistors. Drude model of conductivity. Collision cross section for rigid spheres. Drift velocity. Conductivity. conductors, semiconductors, insulators. Energy dissipation of electric currents. Joule effect. Electromotive force and photovoltaic cells. Circuits and circuit elements. Voltage generators. Kirchhoff's laws. Current sources. Ideal voltage and current generators. Real current and voltage generators. Internal resistance. Slowly variable currents over time. Charge and discharge of capacitors. Outline of electrical conduction phenomena in gases.

 

 

4 - Magnetostatics

 

Magnetic forces. Oersted's experiment. The Lorentz force. Magnetic field. Properties of magnetic forces. The Biot-Savart law. The magnetic field of a stationary current. The divergence of B. Non-existence of magnetic monopoles. Curl of B. Sources of the magnetic field. Ampère's law. Applications of Ampère's law. Volumic and surface current density. Magnetic field of a circular current loop. Magnetic scalar potential. Vector potential. Helmoltz's theorem. Examples of vector potential calculation. Vector potential of a circular loop at large distance. Magnetic dipole. Magnetic field of a dipole. Forces and moments of forces on magnetic dipoles.

 

5 - Electric and magnetic fields varying over time

 

Induced electromotive force. Electromagnetic induction. Faraday's law. Applications of Faraday's law. Motion induced electromotive force. Lenz's law. The induced electric field. Faraday's law and Maxwell's equations. Mutual inductance and self-inductance. Inductors.

Circuits with inductors. LR circuit. Magnetic energy. LC oscillator. Electrodynamics: displacement current and Maxwell's equations in vacuum. Low frequency electrical oscillations. Alternating currents.

 

6 - Magnetism in matter

 

Response of different types of substances to the magnetic field. Diamagnetic, paramagnetic, ferromagnetic materials. Atomic magnetic dipoles. Intrinsic angular momentum of the electron (spin) and magnetic moments. Magnetization and magnetic susceptibility. Microscopic theory of diamagnetism and paramagnetism. The magnetic field of a magnetized body. Volume and surface magnetization current density. Magnetic intensity H. Ampère's law in magnetized materials. Maxwell's equations in matter. Boundary conditions. Qualitative theory of ferromagnetism. Magnets. Linear and non-linear materials. Solving magnetostatic problems with magnetized materials.

 

 

7 - Electrodynamics and electromagnetic waves

 

Electromagnetic waves. Wave equation for the electric field and the magnetic field. Solutions of the wave equation. Monochromatic flat waves. Polarization. Energy and momentum of the electromagnetic field. Poynting's theorem. Momentum of the electromagnetic field. Maxwell stress tensor. Energy and momentum of the electromagnetic wave. Radiation pressure. Propagation of electromagnetic waves in linear media. Reflection and transmission in cases of normal and oblique incidence. Fundamental laws of geometric optics. Formulation of electrodynamics through potentials. Gauge transformations and gauge invariance. Delayed potentials. Quasi-static approximation. Point charges in motion: Lienard-Wiechert potentials. Radiation. Radiation of the electric dipole at great distance. Point charge radiation. Radiated energy and Larmor's formula. Instability of the hydrogen atom in classical electrodynamics. Covariant formulation of electrodynamics. Introduction to the classical theory of the electron: electromagnetic mass and momentum.

 

8 - Electromagnetism and special theory of relativity

 

Postulates of the special theory of relativity. Relativity of simultaneity. Lorentz contraction of lengths and dilation of time. Lorentz transformations. Four-vectors. Lorentz transformations in four-dimensional notation. Four-vector energy - momentum. Relativistic invariance of the electric charge. Electric field in different inertial reference systems. Electric field of a point charge in motion with constant speed. Electric field of a point charge that stops or starts. Relativistic interpretation of the magnetic force. Magnetic field measured in inertial reference systems


Textbook Information

Main textbooks:

1) D.J. Griffiths, Introduction to electrodynamics (IV ed.), Cambridge University Press

2) P. Mazzoldi - M. Nigro - C. Voci, Fisica, vol. II, EdiSES


Consultation:

3) Mencuccini , Silvestrini "Elettromagnetismo e Ottica", Zanichelli

4) E.M. Purcell, La Fisica di Berkeley: Elettricità e Magnetismo, Zanichelli

5) D. Halliday, R. Resnick, K.S. Krane, Fisica, vol. II (III o IV edizione), Ambrosiana

6) E. Amaldi, R. Bizzarri, G. Pizzella, Fisica Generale, Zanichelli

 

Exercise:

7) F. Porto, G. Lanzalone, I. Lombardo, Problemi di Fisica Generale – Elettrom. e Ottica, EdiSES

8) M. Bruno, M. D’Agostino, R. Santoro, Esercizi di Fisica: Elettromagnetismo, Ambrosiana