Subject description - AD0B13MTE

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AD0B13MTE Materials and technology for electronics
Roles:  Extent of teaching:14KP+6KL
Department:13113 Language of teaching:CS
Guarantors:  Completion:Z,ZK
Lecturers:  Credits:4
Tutors:  Semester:Z

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Ability of creative application of materials in electronics is extended in the field of technology of their processing and the change of the properties of materials during their exploitations in electrical circuits, microelectronics, optoelectronic applications, sensors, actuators, superconductors, semiconductors, magnetic structures, and special applications. The processing technologies and the ageing processes are based on the relationships between composition, internal structure, and properties of materials.

Study targets:

Získání poznatků o vlastnostech a chování materiálů pro elektroniku, procesech jejich zpracování a aplikaci těchto poznatků ve výrobě elektronických komponent.

Course outlines:

1. Basic physical-chemical processes in materials processing. Diffusion.
2. Phase transitions. Application of equilibrium phase diagrams.
3. Methods of semiconductor crystallization. Directional crystallization. Zone refining.
4. Epitaxial methods. Vapour and liquid phase epitaxy. MO - Chemical vapour deposition.
5. Physical vapour deposition. Sputtering. Molecular beam epitaxy.
6. Processing of materials in solid state: etching, lithography, micro-fabrication, MEMS.
7. Semiconductor technology: semiconductors processing, P-N junction technology.
8. Materials technology of optoelectronics. LED, OLED, LD, LCD and TFT displays.
9. Materials technology of monolithic and hybrid circuits, wire-bonding, packaging.
10. Printed circuit boards, SMT and THT technology. Joining of electronic materials, welding, soldering, sticking.
11. Technology of ceramic capacitors, MLC, polymer and electrolytic capacitors.
12. Materials technology of transducers and sensors. Materials technology conductors, low temperature superconductors, HTC superconductors.
13. Technology of hard and soft magnetic materials. Materials for data storage in informatics.
14. Ageing of materials, corrosion, electro-migration, polymer degradation.

Exercises outline:

All the exercises are in the form of laboratory work
1) Introduction, basic guidelines for HOS
2) Temperature dependence of ferrite permeability
3) Temperature dependence of capacity of ceramic capacitors
4) Study of electrical properties of polymer composites
5) Dielectric properties of polymers
6) Distribution of impurities in bulk semiconductors
7) Evaluation of soft magnetics from their static hysteresis loops
8) Diffusion in semiconductors
9) Hall measurement
10) Diagnostics of solders for electronics
11) Imperfections in semiconductor crystals
12) Transport properties of metallic conductors
13) Test, Assessment


[1] Bouda,V., Mach, P., Hampl, J.: Properties and Processing of Materials. Textbook CTU FEE, Prague 1999.
[2] Hampl, J., Bouda,V.: Materials for Electrotechnics. Textbook CTU FEE Prague 2000.
[3] Sedláček, J.: Materials and Technology for Electronics - Exercises. Textbook CTU FEE Prague 2007.
[4] Buschow, K.,H.,J.: Magnetic and Superconducting Materials. Elsevier 2005.
[5] Askeland, D., R., Phule., P., P.: The Science and Engineering of Materials. Thomson Brook/Cole 2003.
[6] Mendez., A., Morse. T., F.: Specialty Optical Fibers Handbook. Elsevier Academic Press 2007.
[7] Waser. R.: Nanoelectronics and Information Technology. Wiley VCH Verlag 2003.
[8] Janocha, H.: Adaptronics and Smart Structures. Springer 1999.



Difuze, krystalizace, příprava tenkých vrstev CVD a PVD, technologie MIO, montáž MIO, plošné spoje, OE prvky, aktuátory , senzory, kapacitory, supravodiče, magnetika.

Subject is included into these academic programs:

Program Branch Role Recommended semester

Page updated 15.4.2024 07:51:14, semester: Z/2023-4, Z/2024-5, L/2023-4, Send comments about the content to the Administrators of the Academic Programs Proposal and Realization: I. Halaška (K336), J. Novák (K336)