Maria Teresa MERCALDO | ELEMENTS OF MODERN PHYSICS

cod. 0522200039

ELEMENTS OF MODERN PHYSICS

	0522200039
	DIPARTIMENTO DI MATEMATICA
	EQF7
	MATHEMATICS
	2016/2017

PERCORSO COMUNE Cohort 2015/2016

	YEAR OF COURSE 2
	YEAR OF DIDACTIC SYSTEM 2010
	PRIMO SEMESTRE

TEACHING UNITS

	SSD	CFU	HOURS	ACTIVITY	TYPE OF ACTIVITY
	FIS/02	6	48	LESSONS	SUPPLEMENTARY COMPULSORY SUBJECTS

	Objectives
	THE AIM OF THE COURSE IS TO INTRODUCE MATH STUDENTS TO THE KNOWLEDGE AND UNDERSTANDING OF MODERN PHYSICS, NAMELY TO SPECIAL RELATIVITY AND QUANTUM MECHANICS. THE STUDENTS, AT THE END OF THE COURSE, SHOULD BE ABLE TO APPLY THE ACQUIRED KNOWLEDGE TO SOLVE SIMPLE PROBLEMS OF MODERN PHYSICS.

	Prerequisites
	KNOWLEDGE OF MECHANIC, THERMODYNAMIC AND ELECTROMAGNETISM IS REQUIRED.

	Contents
	INTRODUCTION TO SPECIAL RELATIVITY. EINSTEIN’S POSTULATES. LORENTZ TRANSFORMATIONS. RELATIVISTIC DYNAMICS. THE FOUR-MOMENTUM. RELATIVISTIC ENERGY. THE MASS-ENERGY RELATION. ELASTIC WAVES. STANDING WAVES. WAVES ON VIBRATING STRINGS. ELECTROMAGNETIC WAVES. ELECTRODYNAMIC POTENTIALS. COVARIANCE OF ELECTRODYNAMICS. ELECTROMAGNETIC TENSOR. TRANSFORMATION OF ELECTROMAGNETIC FIELDS BY LORENTZ TRANSFORMATIONS. INTERFERENCE. YOUNG EXPERIMENT. DIFFRACTION. RAYLEIGH SCATTERING. INTRODUCTION TO QUANTUM MECHANICS. PHOTOELECTRIC EFFECT. COMPTON EFFECT. WAVE-PARTICLE DUALITY. DE BROGLIE’S HYPOTHESIS. SCHRÖDINGER EQUATION. HEISENBERG UNCERTAINTY RELATIONSHIPS. POSTULATES OF QUANTUM MECHANICS. QUANTUM HARMONIC OSCILLATOR.

INTRODUCTION TO SPECIAL RELATIVITY. EINSTEIN’S POSTULATES. LORENTZ TRANSFORMATIONS. RELATIVISTIC DYNAMICS. THE FOUR-MOMENTUM. RELATIVISTIC ENERGY. THE MASS-ENERGY RELATION.

ELASTIC WAVES. STANDING WAVES. WAVES ON VIBRATING STRINGS. ELECTROMAGNETIC WAVES. ELECTRODYNAMIC POTENTIALS. COVARIANCE OF ELECTRODYNAMICS. ELECTROMAGNETIC TENSOR. TRANSFORMATION OF ELECTROMAGNETIC FIELDS BY LORENTZ TRANSFORMATIONS.
INTERFERENCE. YOUNG EXPERIMENT. DIFFRACTION. RAYLEIGH SCATTERING.

INTRODUCTION TO QUANTUM MECHANICS. PHOTOELECTRIC EFFECT. COMPTON EFFECT. WAVE-PARTICLE DUALITY. DE BROGLIE’S HYPOTHESIS. SCHRÖDINGER EQUATION. HEISENBERG UNCERTAINTY RELATIONSHIPS. POSTULATES OF QUANTUM MECHANICS. QUANTUM HARMONIC OSCILLATOR.

	Teaching Methods
	FRONTAL LESSONS; PROBLEMS AND EXERCISES.

	Verification of learning
	ORAL EXAMINATION.

	Texts
	R. RESNICK, "INTRODUCTION TO SPECIAL RELATIVITY" (WILEY); J.D. JACKSON, “CLASSICAL ELECTRODYNAMICS” (WILEY) R. P. FEYNMAN, "THE FEYNMAN LECTURES ON PHYSICS, VOL. 3" C. COHEN-TANNOUDJI, B. DIU, F. LALOË, “QUANTUM MECHANICS” (WILEY) K. S. KRANE, "MODERN PHYSICS" P. A. TIPLER, "PHYSICS FOR SCIENTISTS AND ENGINEERS: VOL. 3 MODERN PHYSICS"

	More Information
	FOR OTHER INFORMATION AND THE DETAILED PROGRAM OF THE COURSE VISIT THE FOLLOWING WEB PAGE: HTTP://WWW.FISICA.UNISA.IT/MARIATERESA.MERCALDO/DIDATTICA/FISICAMODERNA.HTML

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Maria Teresa MERCALDO | ELEMENTS OF MODERN PHYSICS

ELEMENTS OF MODERN PHYSICS

PERCORSO COMUNE Cohort 2015/2016

TEACHING UNITS

PROFESSORS

SHEET

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Maria Teresa MERCALDO | ELEMENTS OF MODERN PHYSICS