Content:
Theory teaching
Lectures on: magnetic properties of matter (magnetic moments of electrons and atoms, diamagnetism, paramagnetism, ferromagnetism); fundamentals of Maxwell’s theory of electromagnetism; electromagnetic oscillations (oscillatory circuit, differential equation of free damped electromagnetic oscillations, differential equation of forced electromagnetic oscillations, resonance of electromagnetic oscillations, alternating current); electromagnetic waves (spectrum, differential equations, energy); quantum nature of radiation (heat radiation and properties, absolute black body radiation, Stefan-Boltzmann law, Wien’s law, Planck’s law of radiation, photoelectric effect, Compton effect); Bohr’s theory of the hydrogen atom (Bohr’s postulates, linear spectrum of the hydrogen atom); elements of quantum mechanics (corpuscular-wave properties of matter, de Broglie wave, uncertainty principle, wave function and statistical interpretation, general form of Schrodinger’s equation for stationary states, free particle motion, particle in a potential well, tunnel effect, linear harmonic oscillator in quantum mechanics); elementary modern physics of atoms and molecules (hydrogen molecule in quantum mechanics, spin quantum number, fermions and bosons, Pauli’s principle, Mendeleev’s periodic table, X-ray spectra, molecular spectra, lasers); elementary physics of solids (zonal theory, metals, semiconductors, conductors, conductivity of doped semiconductors, photoconductivity of semiconductors, p-n junction, transistors, metal-semiconductor contacts). Practical teaching
Calculation and demonstration-experimental assignments. |
