Structure and Properties of Materials
FEKT-LSVMAcad. year: 2019/2020
Composition, structure and properties of materials. Regulation of materials properties. Glass and ceramic for electronics, glass cements. Glass crystalline materials. Ceramic superconductors. Piezoelectrics. Compound and amorphous semiconductors, semiconductors films. Organic semiconductors. Magnetic metal glass. Materials for magnetic recording. Materials for optoelectronics. Fibre optics. Storage materials. Biomaterials and biocompatibility. High-purity materials. Composites. Conducting plastics. High-vacuum materials.
Learning outcomes of the course unit
At the end of the course, the student will be able to:
- classify electrical materials from the point of view of their properties and usage,
- explain nature of physical phenomena that take place in the structure of electrical materials,
- describe physical phenomena that take place in the electrical materials mathematically,
- describe mutual relation between composition and structure of materials and resulting properties and possibilities of controlling of these properties,
- project optimal kinds of materials for production of electrical, electronic and microelectronic devices, as well as for applications in related technical and scientific fields.
Knowledge of electrical materials on the level of the bachelor's course Materials and technical documentation.
Recommended optional programme components
Recommended or required reading
Mentlík, V. Dielektrické prvky a systémy, BEN, Praha 2006, ISBN 80-7300-189-6 (CS)
Kazelle, J., Liedermann, K., Jirák, J., Havlíček, Vaněk, J.: Elektrotechnické materiály a výrobní procesy. Elektronické texty, Brno 2002. (CS)
Askeland, D. R.: The Science and Engineering of Materials, Boston 1994, USA, ISBN 0-534-93423-4 (EN)
Kocman, V.: Fyzika a technologie elektrotechnických materiálů - Izolanty A, Skripta SNTL, Praha 1971 (CS)
Kocman, V.: Fyzika a technologie elektrotechnických materiálů - Izolanty B, Skripta SNTL, Praha 1972 (CS)
Planned learning activities and teaching methods
Teaching methods include lectures, numerical exercises and practical laboratories. Course is taking advantage of virtual laboratories freely available on server.
Assesment methods and criteria linked to learning outcomes
up to 40 points during the semester (15 points from laboratory seminars and 25 points from written test)
up to 60 points from written final exam
Final exam is focused on verification of knowledge and orientation in the field of electrical materials.
Language of instruction
Composition, structure and properties of materials. Approaches to regulation of materials properties.
Non-traditional and heat-resistant plastics. Conducting composites.
Glass for electronics. Glass cements. Sintered glasses. Glass crystalline materials.
Ceramic for electronics. Ceramic superconductors. Piezoelectrics.
Amorphous semiconductors. Organic semiconductors. Semiconducting films.
Magnetic metal glasses. Materials for magnetic recording.
Materials for optoelectronics. Fibre optics.
High-purity materials for electronic and other purposes.
Materials for conversion of energy. Storage materials.
Bio-materials and bio-compatibility.
Materials and working environment.
The aim of the course is to acquaint students with the mutual relation of composition and structure of materials on their properties and approaches to regulation of materials properties. The knowledge of these relation enables to design optimal sorts of materials for electrical, electronic and microelectronic manufacturing and applications in related technical and scientific branches.
Specification of controlled education, way of implementation and compensation for absences
Obligatory participation in teaching.
Type of course unit
12 hours, compulsory
Teacher / Lecturer
14 hours, compulsory
Teacher / Lecturer
eLearning: currently opened course