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Materials for Electrotechnics

* Exchange students do not have to consider this information when selecting suitable courses for an exchange stay.

Course Unit Code637-2004/02
Number of ECTS Credits Allocated5 ECTS credits
Type of Course Unit *Choice-compulsory type B
Level of Course Unit *First Cycle
Year of Study *Third Year
Semester when the Course Unit is deliveredWinter Semester
Mode of DeliveryFace-to-face
Language of InstructionCzech
Prerequisites and Co-Requisites Course succeeds to compulsory courses of previous semester
Name of Lecturer(s)Personal IDName
DRA30prof. Ing. Jaromír Drápala, CSc.
SZU02doc. Ing. Ivo Szurman, Ph.D.
Summary
The course "Materials for Electrical Engineering" represents a general basis for studies and it provides to students an overview of materials that are used at designing of various electrical, opto-electronic and micro-electronic devices. It deals namely with electrical, magnetic, physical-chemical, mechanical and other properties of substances and it puts them into relation with composition and internal structure of materials. The course also focuses on the processes of preparation of individual kinds of materials by current technologies related to electronics and micro-electronics, used materials and trends associated with the miniaturisation of electronic systems. Explanation of electrical materials will be conducted according to the scheme: Structure and properties of materials, conductive materials, super-conductors, semi-conductors, micro-electronics and opto-electronics, magnetic materials, dielectric and insulating materials and special structural materials.
Learning Outcomes of the Course Unit
- Student will be able to define and apply basic theoretical knowledge on influence of composition and internal structure of material on its physical, mechanical, electrical, magnetic and optical properties.
- Student will get an overview of the current and perspective materials for applications in electrical engineering, micro-electronics and opto-electronics.
- Student will be able to classify and explain the fundamental technologies for preparation of passive and active electronic elements.
- Student will be able to propose material that will be suitable for concrete passive or active elements in electric engineering.
- Student will be able to evaluate and apply findings from theory at designing optimal technologies (such as growth of crystals, micro-alloying, epitaxy, diffusion).
Course Contents
1. Electron theory of the metallic state. Cohesion forces in the solid state; types of elementary bonds and their influence on physical properties of materials. Quantum, electron and band theories of the conductivity.
2. Basic characteristics and requirements to materials for electric engineering and microelectronics. Physical, chemical and physical-chemical methods of refining and synthesis of metallic and non-metallic materials and their characterisation.
3. Methods of preparation of highly pure and structurally defined materials with monocrystalline structure for new types of electronic, opto-electronic and magnetic components. Influence of electrically active elements on properties of electronic components.
4. Conductors. Physical principle of the electrical conductivity of metals, basic characteristic of conductors. Metallic conductive materials and their alloys, carbon based materials.
5. Special conducting materials. Materials for electric contacts, resistors, thermocouples, bimetals, solders, metals and alloys for safety-fuses, materials with shape memory, materials for vacuum electric engineering.
6. Superconductivity. Superconductive materials. Low- and high-temperature superconductors.
7. Magnetic materials. Basic concepts, physics of the ferromagnetism, properties of magnetic materials. Basic types of magnetic materials. Metallic soft magnetic material, metallic glasses. Magnetically hard materials. Ferrites. Structure, division, technology of production, properties and field of application.
8. Dielectrics and insulating materials, characteristics and structure of insulators, polarisation and permittivity of dielectrics, dielectric rigidity of solid insulators, breakdown and basic kinds of breakdown, non-electrical properties of insulators, Gaseous, liquid and solid state insulators, inorganic, organic and synthetic insulating materials.
9. Oxide materials – ferro-electrics, materials for bubble memories (garnets). Liquid crystal - nematic, lamellar and columnar systems, structure and its transformation. Materials for special purposes, whiskers. Composite materials.
10. Physical properties and main kinds of semiconductor materials. Theory of conductivity in semiconductors. Semiconductor materials: elementary superconductors, compounds and oxide. Influence of external effects on properties of semiconductors.
11. Basic technologies for production of semiconductor materials and integrated circuits, planar epitaxial technology at production of integrated circuits applied in the micro-electronics, evolution and types of technologies for preparation of substrates, principles of the photo-lithography, basic materials used at creation of structures of semiconductors.
12. Mechanism of elementary preparation of active elements with use of epitaxy, vapour plating (evaporation), sputtering and ion implantation, application of diffusion processes in semiconductors at creation of P- N junctions.
13. Opto-electronics – radiation generators and detectors, waveguides. Compounds AIIIBV, AIIBVI …, laser technology, solar cells.
14. Nano-materials and nano-electronics. Material engineering in electric engineering and microelectronics.
Recommended or Required Reading
Required Reading:
[1] http://katedry.fmmi.vsb.cz/Opory_FMMI_ENG/2_rocnik/AEM/Materials%20for%20Electrotechnics%20and%20Microelectronics.pdf.
[2] HAMPL, J. a V. BOUDA. Materials for electrotechnics. Praha: České vysoké učení technické, c1995. ISBN 80-01-01300-6.
[1] http://www.person.vsb.cz/archivcd/FMMI/ETMAT/index.htm.
[2] ROUS, B. Materiály pro elektroniku a mikroelektroniku. Praha: SNTL - Nakladatelství technické literatury, 1991. ISBN 80-03-00617-1.
[3] BOUDA, V. Materiály pro elektrotechniku. Praha: Vydavatelství ČVUT, 2000. ISBN 80-01-02232-3.
Recommended Reading:
[1] DORF, R.C., ed. The electrical engineering handbook. Boca Raton: CRC Press, c1993. ISBN 0-8493-0185-8.
[2] SOLYMAR, L., D. WALSH a R.R.A. SYMS. Electrical properties of materials. 9th ed. Oxford: Oxford University Press, 2014. ISBN 978-0-19-870277-1.
[3] WHITAKER, J.C. Microelectronics. 2nd Ed. Boca Raton: CRC Press, 2006. ISBN 0-8493-3391-1.
[4] HARPER, Ch.A. Electronic Materials and Processes Handbook. New York: McGraw-Hill, 2004. ISBN 0-07-140214-4.
[1] ŠESTÁK, J., Z. STRNAD a A. TŘÍSKA. Speciální technologie a materiály. Praha: Academia, 1993. ISBN 80-200-0148-4.
[2] BOUDA, V., P. MACH, J. PETR. a K. ŠTUPL. Vlastnosti a technologie materiálů. Vyd. 2. Praha: ČVUT, 1998. ISBN 80-01-01839-3.
[3] LIPTÁK, J. a J. SEDLÁČEK. Úvod do elektrotechnických materiálů. V Praze: České vysoké učení technické, 2008dotisk. ISBN 978-80-01-03191-9.
[4] DORF, R.C., ed. The electrical engineering handbook. Boca Raton: CRC Press, c1993. ISBN 0-8493-0185-8.
Planned learning activities and teaching methods
Lectures, Seminars, Tutorials, Experimental work in labs, Project work
Assesment methods and criteria
Task TitleTask TypeMaximum Number of Points
(Act. for Subtasks)
Minimum Number of Points for Task Passing
Credit and ExaminationCredit and Examination100 (100)51
        CreditCredit45 25
        ExaminationExamination55 15