Coursework requirements - conditions for taking the exam The results and discussions will be documented by a short but highly specialized technical report. The third part of the course (Methodology) will be given as a workshop or seminar where various methods for defining material indexes in each application area will be discussed and be implement/tested. This work will be supervised by the lecturer. A technical report will be written, and the report will provide a proper review of the literature together with an analysis or evaluation for national technological development in the field. The second part of the course (Applications) will be group work where students will conduct intensive literature search on a self-chosen application field. The first part of the course (Fundamentals) will be given by a combination of lectures, exercises and home assignments. GRANTA material database and material choices.
Material indexes method associated with concrete applications Part III: Methodology for industrial applications: Electron holes and their roles in diodes p-n joint In terms of band structureĬharged carrier distribution in intrinsic and doped semiconductors. Periodic potential and formation of energy band structureĬlassification of metals, semiconductors and insulator. Heat capacity originated from lattice vibration and thermo-conductivity Reciprocal lattices and its determination and the concept Brillouin-zonesĮquilibrium concentration of point defects and its relationship with temperature and pressure Semiconductors: Band-gap, Charge carrier, doping, p-n joint and photovoltage effect State density and Fermi level and their relation to electrical conductivityĮlectron in periodic potentials: Energy band, band-gap and classification of materials Lattices/defects in real materials and their roles in thermo-/electrical conductivityįree Fermi electron gas theory. Periodic structure, and associated reciprocal space, and its application in diffraction experiment The course will focus on following subjects: The emphasis is placed on the understanding of the fundamental phenomena and corresponding principles related to the contemporary development in materials science. The course provides an introduction to solid state physics and its application to the modern energy technologies. The student can communicate and disseminate in their independent practice in research and development.
Is capable to participate actively in scientific research and development. Has a broad overview of application and contemporary development related to energy technologies.Ĭan disseminate main ideas and principles related to materials associated with energy technologiesĬan use advanced methods for material choice using the material database GRANTAĬan analyze and evaluate materials with various sets of criteria or material indexesĬan conduct preliminary scientific analysis and technical evaluation of materials associated with energy technologiesĬan make proper evaluation of technical constructions/instrumentations associated with energy technologies Has advanced knowledge of some central topics of solid state physics The student's learning outcomes after completing the course
Recommended requirementsĪn advanced knowledge and skills in physics and advanced mathematics. Master in Green Energy Technology (Compulsory in Materials for Energy Technology profile). The course is connected to the following study programs
0 kommentar(er)
