This is a graduate-level survey of how electrons, photons, and spins actually behave inside solids, building from band theory up to the device-scale and bulk-response phenomena that follow from it. You'll work through the physics behind semiconductor junctions and optoelectronic devices, dielectric polarization mechanisms, the different flavors of magnetic ordering, and wave propagation in real media, with the course assessed primarily through a presentation rather than exams. It sits at the bridge between solid-state physics and applied materials engineering — useful preparation if you're heading toward research in electronic, photonic, or magnetic materials, since later device-design and characterization work assumes you already understand why a material behaves the way it does.
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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