Content The course begins with a summary of concepts and relationships in quantum mechanics and statistical physics that are needed for elementary solid state physics. This is followed by a review of the structure of crystals. The course treats electrical and thermal properties of crystalline elements and the properties of these properties depending on various variables such as e.g. temperature. The free electron model and the near-free electron model are used to describe the electrical and thermal properties of simpler metals. The concept of holes is introduced for semiconductors and is applied to the electrical properties of intrinsic and extrinsic semiconductors. Lattice dynamics is described through the introduction of the phonon concept. The Debey model is used to describe heat capacity, volume expansion and thermal conductivity of insulators. The course includes compulsory laboratory work. The course comprises a theory module of 6.5 credits and a laboratory module of 1 credits.
Expected study results To fulfil the goals of knowledge and understanding, the student should be able to:
describe the crystal structure of the most common cubic and hexagonal structures
explain how the reciprocal lattice can be used to explain X-ray scattering against crystals and define Brillouin zones
explain differences in the electrical conductivity between metals, insulators and semiconductors based on a band structure model.
To fulfil the goals for proficiency and ability, the student should be able to:
perform calculations of reciprocal lattice parameters for cubic structures
determine electrical transport properties of metals and semiconductors based on free electron and band structure models
calculate the heat capacity based on the Debye model and the free electron model
analyse and discuss measurement data based on theoretical models
summarise, present and communicate results from experiments
collaborate with other students during laboratory work.
To fulfil the goals for values and critical approach, the student should be able to:
demonstrate awareness of ethical aspects of scientific work such as a correct approach to cheating and plagiarism.
Eligibility Modern Physics 4.5 credits or equivalent. Fundamentals of Electromagnetism 6 credits and Wave Physics and Optics 6 credits alternatively Electrical and wave motion theory 7.5 credits or equivalent.
Forms of instruction The teaching is conducted in the form of lectures, lessons, problem solving sessions, and supervision during laboratory work. The labs are mandatory. In addition to scheduled activities, individual work with the course material is also required.
Examination The examination on the course's theory module takes place individually in the form of a written examination at the end of the course. On the written examination, one of the grades Fail (U), Pass (3), Pass with Merit (4) or Pass with Distinction (5).
The examination of the course's laboratory module takes place in groups, with individual assessment, through written reports and oral presentations. On written reports and on oral presentations, one of the grades Fail (U) or Pass (G) is given. On the entire module, one of the grades Fail (U) or Pass (G) is given. The grade Pass (G) is set only when all reports and accounts are approved.
On the entire course, one of the grades Fail (U), Pass (3), Pass with Merit (4) or Pass with Distinction (5). To pass the entire course, all modules must be passed. Provided that all modules are passed, the grade for the entire course will be the same as for the theory module. Those who have passed a test may not undergo a re-exam for higher grades.
Literature Solid State Physics Hook John R., Hall Henry Edgar 2. ed. : Chichester : Wiley : 1991 : xxi, 474 p. : ISBN: 0-471-92804-6
