Low Temperature Solid State Physics: Some Selected Topics

absorption alloys anomaly anti-ferromagnetic assume behaviour calculated carriers coefficient conduction band considered constant copper crystal lattice Curie's law curve Debye decrease defects density determined dipole direction dislocation donor effect electrical resistivity energy gap energy levels entropy excited experimental experiments Fermi surface ferromagnetic field H free electron frequency function germanium give given hence higher temperatures impurity atoms increase interaction ionization ions isotope low temperatures magnetic field magnetic moment maximum mean free path measurements mechanism metal mobility normal number of electrons observed obtained occur oersted orbital oscillations p-type paramagnetic phonon proportional region resonance room temperature salt sample scattering Schottky semiconductors shown in Fig shows specific heat specific-heat specimen spin split superconducting susceptibility tempera temperature dependence temperature is reduced theory thermal conductivity thermal resistivity thermopower tion transition ture u-processes valence band velocity wave vector wavelength Whilst Ziman