Modern theory of solids, Schottky junction, pn junction, transistors, LEDs, solar cells, matter polarization and permittivity, polarization mechanisms, frequency dependence of dielectric constant and loss, capacitors, piezoelectricity, magnetization of matter, diamagnetism, paramagnetism, ferromagnetism, antiferromagnetism, ferrimagnetism, light propagation in homogeneous medium, refractive index, dispersion, Snell's law, Fresnel's equations, absorption, optical anisotropy.
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Course Learning Outcomes: Course Learning Outcome Assessment •Be able to apply basic knowledge on microscopic physical models to describe material properties. •Have a solid background on material properties by learning the most fundamental models in materials science. •Relate electrical, optical, and magnetic properties of materials with the electronic and atomic structure. •Gain interdisciplinary research skills, and if applicable, utilize these skills to advance projects to engineer novel devi
Introduction to course Modern theory of solids Semiconductor electronic devices Semiconductor optoelectronic devices Dielectric materials and insulation I Dielectric materials and insulation II Magnetization of matter Magnetic material classifications Origin of ferromagnetism Light waves in a homogeneous medium Refractive index and absorption Dispersion: refractive index – wavelength behavior Optical anisotropy Presentations ECTS - Workload Table: Activities Number Hours Workload Total Workload: 0 Total Workload / 30: 0 / 30 0 ECTS Credits of the Course: 5