Mazzoldi Nigro Voci Fisica 2 Elettromagnetismo E Onde Pdf 259: The Best Book for Physics Students
Mazzoldi Nigro Voci Fisica 2 Elettromagnetismo E Onde Pdf 259: A Comprehensive Guide to Physics
If you are looking for a book that covers the topics of electromagnetism and waves in a clear and rigorous way, you might want to check out Mazzoldi Nigro Voci Fisica 2 Elettromagnetismo E Onde Pdf 259. This book is written by three professors of physics from the University of Padua, Italy, and it is the second volume of a series that also includes mechanics and thermodynamics.
Mazzoldi Nigro Voci Fisica 2 Elettromagnetismo E Onde Pdf 259
In this article, we will give you an overview of what you can find in this book, and why it is a valuable resource for physics students and enthusiasts.
What is Mazzoldi Nigro Voci Fisica 2 Elettromagnetismo E Onde Pdf 259?
Mazzoldi Nigro Voci Fisica 2 Elettromagnetismo E Onde Pdf 259 is a textbook that covers the classical theory of electromagnetism and optics, both geometric and physical. It is divided into 12 chapters, each with an introduction, a theoretical section, a summary, and a set of exercises with solutions.
The book follows a logical and pedagogical order, starting from the basic concepts of electric charge, force, and field, and then moving on to more advanced topics such as electric potential, capacitance, current, resistance, magnetic force and field, electromagnetic induction, Maxwell's equations, electromagnetic waves, reflection and refraction, interference and diffraction, polarization, dispersion, and absorption.
The book also includes some historical notes and biographical sketches of the scientists who contributed to the development of electromagnetism and optics, such as Coulomb, Faraday, Ampere, Gauss, Lorentz, Hertz, Fresnel, Young, Malus, Brewster, Snell, Newton, and Einstein.
Why should you read Mazzoldi Nigro Voci Fisica 2 Elettromagnetismo E Onde Pdf 259?
There are many reasons why you should read Mazzoldi Nigro Voci Fisica 2 Elettromagnetismo E Onde Pdf 259 if you are interested in physics. Here are some of them:
The book is comprehensive and covers all the essential aspects of electromagnetism and optics that you need to know for your studies or your curiosity.
The book is clear and rigorous and explains the physical phenomena and the mathematical formulas with examples and diagrams.
The book is updated and reflects the current state of knowledge and research in the field of electromagnetism and optics.
The book is adaptable and can be used for different courses and levels of study.
The book is accessible and can be downloaded for free from the internet as a PDF file.
How can you get Mazzoldi Nigro Voci Fisica 2 Elettromagnetismo E Onde Pdf 259?
If you want to get Mazzoldi Nigro Voci Fisica 2 Elettromagnetismo E Onde Pdf 259, you have two options:
You can buy the printed version of the book from EdiSES s.r.l., the publisher that specializes in scientific books. The price is around 40 euros.
You can download the PDF version of the book for free from various websites that host academic documents. One of them is vdocuments.net, where you can find the book under the index "1".
Either way, you will get a high-quality book that will help you learn more about electromagnetism and waves in physics.
What are the main topics of Mazzoldi Nigro Voci Fisica 2 Elettromagnetismo E Onde Pdf 259?
In this section, we will give you a brief overview of the main topics that are covered in Mazzoldi Nigro Voci Fisica 2 Elettromagnetismo E Onde Pdf 259. Each chapter has a more detailed explanation and derivation of the formulas and concepts, as well as examples and exercises.
Chapter 1: Electric force and field
This chapter introduces the concept of electric charge and its conservation, the Coulomb's law for the electric force between two point charges, the principle of superposition for multiple charges, the electric field and its representation by field lines, the electric flux and the Gauss's law for the electric field.
Chapter 2: Electric potential
This chapter defines the concept of electric potential and potential difference, the relation between electric field and potential, the potential energy of a system of charges, the equipotential surfaces and their properties, the calculation of electric potential for various charge distributions, and the applications of electric potential to capacitors and dielectrics.
Chapter 3: Electric current
This chapter describes the phenomenon of electric current and its measurement by ammeters, the Ohm's law for the relation between current, voltage, and resistance, the Kirchhoff's laws for current and voltage in a circuit, the power and energy dissipated by a resistor, the resistivity and conductivity of materials, and the applications of electric current to batteries, electromotive force, internal resistance, RC circuits, and Wheatstone bridge.
Chapter 4: Magnetic force and field
This chapter introduces the concept of magnetic force and its direction by the right-hand rule, the magnetic force on a moving charge and on a current-carrying wire, the torque on a current loop in a magnetic field, the magnetic dipole moment and its relation to angular momentum, the magnetic field and its representation by field lines, the Biot-Savart law for calculating the magnetic field due to a current element, and the Ampere's law for calculating the magnetic field due to a closed current loop.
Chapter 5: Electromagnetic induction
This chapter explains the phenomenon of electromagnetic induction and its discovery by Faraday and Henry, the Faraday's law for calculating the induced electromotive force due to a changing magnetic flux, the Lenz's law for determining the direction of induced current and its conservation of energy principle, the self-induction and mutual induction of coils, the inductance and its calculation for various geometries, the energy stored in a magnetic field, and the applications of electromagnetic induction to generators, transformers, RL circuits, LC circuits, RLC circuits, and AC circuits.
Chapter 6: Maxwell's equations
This chapter summarizes the four fundamental equations that describe electromagnetism in a unified way: Gauss's law for electric field, Gauss's law for magnetic field (or absence of magnetic monopoles), Faraday's law of induction (or Maxwell-Faraday equation), and Ampere-Maxwell law (or Maxwell-Ampere equation). It also shows how these equations imply that light is an electromagnetic wave that propagates in vacuum with a constant speed equal to c = 1/sqrt(epsilon_0 mu_0), where epsilon_0 is the permittivity of free space and mu_0 is the permeability of free space.
Chapter 7: Electromagnetic waves
This chapter derives the wave equation for electromagnetic waves from Maxwell's equations in vacuum or in linear isotropic homogeneous media. It also describes the properties of electromagnetic waves such as their polarization state (linear, circular, or elliptical), their intensity (or irradiance) proportional to their amplitude squared (or Poynting vector), their energy density (or energy flux) proportional to their intensity divided by c (or Poynting vector divided by c), their momentum density proportional to their energy density divided by c (or Poynting vector divided by c^2), their pressure proportional to their momentum density (or radiation pressure), their frequency (or angular frequency) related to their wavelength (or wave number) by c = lambda f (or omega = ck), their phase velocity equal to c in vacuum or c/n in media (where n is
the refractive index), their group velocity equal to d omega / dk in dispersive media (
Chapter 8: Reflection and refraction
This chapter applies the boundary conditions for electromagnetic waves at the interface between two media with different refractive indices. It also derives the laws of reflection and refraction (or Snell's law) for both normal and oblique incidence, the Fresnel's equations for calculating the reflection and transmission coefficients for both polarizations (s and p), the Brewster's angle for which the reflected wave is completely polarized, the total internal reflection and the critical angle for which the refracted wave is parallel to the interface, and the evanescent wave and the Goos-Hanchen shift for the case of total internal reflection.
Chapter 9: Interference and diffraction
This chapter explains the phenomenon of interference and diffraction of electromagnetic waves due to multiple sources or apertures. It also describes the Huygens-Fresnel principle for calculating the amplitude of a wave at a point as a superposition of spherical waves emitted by each point of a wavefront, the Young's double slit experiment for demonstrating interference fringes, the interference in thin films due to multiple reflections, the diffraction by a single slit and its relation to the resolution limit of an optical instrument, the diffraction by a circular aperture and its relation to the Airy disk, the diffraction by a double slit and its relation to the interference pattern, the diffraction grating and its relation to the angular dispersion of wavelengths, and the Michelson interferometer and its relation to measuring small distances or wavelength shifts.
Chapter 10: Polarization
This chapter defines the concept of polarization of electromagnetic waves as the orientation of their electric field vector in space. It also classifies polarization states into linear, circular, and elliptical, and shows how to represent them by Jones vectors and matrices. It also describes various devices and methods for producing, analyzing, or modifying polarization states, such as polarizers, wave plates (or retarders), optical activity (or circular birefringence), dichroism (or linear birefringence), Kerr effect (or electro-optic effect), Pockels effect (or electro-optic effect), Faraday effect (or magneto-optic effect), and optical modulators.
Chapter 11: Dispersion and absorption
This chapter studies the phenomenon of dispersion and absorption of electromagnetic waves in media with complex refractive index. It also defines the real part of refractive index as related to phase velocity and wavelength in media, and the imaginary part of refractive index as related to attenuation coefficient and intensity in media. It also derives the Kramers-Kronig relations that link dispersion and absorption by causality principle. It also describes various types of dispersion such as normal dispersion (or positive dispersion), anomalous dispersion (or negative dispersion), group velocity dispersion (or pulse broadening), chromatic dispersion (or wavelength dependence of refractive index), material dispersion (or frequency dependence of refractive index), waveguide dispersion (or mode dependence of refractive index), modal dispersion (or mode mixing in multimode fibers), polarization mode dispersion (or polarization dependence of group velocity in birefringent fibers), and nonlinear effects such as self-phase modulation (or intensity dependence of refractive index).
Chapter 12: Optical fibers
This chapter introduces the concept of optical fibers as cylindrical waveguides that confine electromagnetic waves by total internal reflection. It also derives
In this article, we have given you a brief overview of what you can find in Mazzoldi Nigro Voci Fisica 2 Elettromagnetismo E Onde Pdf 259, a comprehensive and rigorous textbook that covers the classical theory of electromagnetism and optics. We have also shown you why this book is a valuable resource for physics students and enthusiasts, and how you can get it either as a printed version or as a free PDF file. We hope that this article has sparked your interest in learning more about electromagnetism and waves in physics, and that you will enjoy reading Mazzoldi Nigro Voci Fisica 2 Elettromagnetismo E Onde Pdf 259. b99f773239