OPTICS AND QUANTUM ELECTRONICS
(objectives)
- to make the student familiar with the principal experimental results who led to the reformulation of physics needed in order for atomic phenomena to be adequately described; - to introduce students to the concept wave function and to Schroedinger's equation; - to provide those mathematical tools needed to solve some problems concerning simple quantum systems (potential well, harmonic oscillator); - to provide a quantum interpretation about the behaviour of some complex systems (like for instance hydrogen-like atoms, spin, field quantization, band theory, effective mass)
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Code
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20810065 |
Language
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ITA |
Type of certificate
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Profit certificate
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Module: QUANTUM ELECTRONICS
(objectives)
- to make the student familiar with the principal experimental results who led to the reformulation of physics needed in order for atomic phenomena to be adequately described- to introduce students to the concept wave function and to Schroedinger's equation- to provide those mathematical tools needed to solve some problems concerning simple quantum systems (potential well, harmonic oscillator)- to provide a quantum interpretation about the behaviour of some complex systems (like for instance hydrogen-like atoms, spin, field quantization, band theory, effective mass)
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Code
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20810065-1 |
Language
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ITA |
Type of certificate
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Profit certificate
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Credits
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6
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Scientific Disciplinary Sector Code
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FIS/03
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Contact Hours
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48
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Type of Activity
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Related or supplementary learning activities
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Teacher
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GABRIELLI ANDREA
(syllabus)
Probability theory Random variables Averages and expected values Examples of probability distributions Boltzmann's statistics Black body radiation Planck's law Photoelectric effect Compton's effect Rutherford's model Bohr's quantum theory de Broglie's waves Schroedinger's equation for free particles The superposition principle The uncertainty principle On the probabilistic meaning of the wavefunction Physical observables and operators Schroedinger's equation with forces Eigenvalues and eigenfunctions Stationary states Potential step Potential barriere: tunnelling Quantum theory of alpha radioactive decay Infinite potential well 2D rigid rotator: selection rules Harmonic oscillator Vibrations of diatomic molecules Electron in a crystal: Bloch's theorem Effective mass
(reference books)
1) "Quantum Mechanics ", B.H. Bransden and C.J. Joachain;
2) "Quantum Physics", S. Gasiorowicz;
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Dates of beginning and end of teaching activities
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From 26/09/2022 to 13/01/2023 |
Delivery mode
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Traditional
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Attendance
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not mandatory
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Evaluation methods
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Oral exam
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Module: OPTICS |
Code
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20810065-2 |
Language
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ITA |
Type of certificate
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Profit certificate
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Credits
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6
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Scientific Disciplinary Sector Code
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FIS/03
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Contact Hours
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48
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Type of Activity
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Related or supplementary learning activities
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