Fundamentals of Materials Science

Major: Biomedical Engineering (Internet of Things)
Code of subject: 6.163.03.O.050
Credits: 4.00
Department: Electronics and Information Technology
Lecturer: Corneliia Tovstyuk
Semester: 4 семестр
Mode of study: денна
Learning outcomes: The study of an educational discipline involves the acquisition of the following competencies by students of education: General competences (CG): ZK2. Knowledge and understanding of the subject area and understanding of professional activity. ZK5. Ability to conduct research at an appropriate level Professional competences (FC): FC8. Ability to make informed decisions FC9. Ability to communicate with representatives of other professional groups at different levels (with experts from other fields of knowledge/types of economic activity). Special professional competences (FCS): FK2.1. Ability to apply engineering software packages for research, analysis, processing and presentation of results, as well as for automated design of medical devices and systems. FK2.3. Ability to learn and apply new methods and tools for analysis, modeling, design and optimization of medical devices and systems.
Required prior and related subjects: Higher mathematics, physics, chemistry.
Summary of the subject: Basic information about the features of chemical bonds. Crystal structures. Physical processes in conductors and their properties. Crystallization process, allotropy and crystal defects. Mechanical properties of materials and their definition. Superconductivity. Basic information about feet. Conductive materials. Materials of high conductivity and conductive feet of high resistance. Electron gas in metals. Properties of the most widely used semiconductors.
Assessment methods and criteria: To control the results of student learning in the process of current and The following methods are provided for semester control: current control over the implementation of practical works and their protection; testing in a virtual learning environment; presentation of an individual task; oral explanation of the individual sections. Laboratory works are evaluated for 3 points. 3 points - ("excellent") is awarded for a high level of knowledge (allowed some inaccuracies) of the educational material, the ability to analyze the phenomena being studied, in their relationship and development, clearly, succinctly, logically, consistently respond to asked questions, the ability to apply theoretical provisions during solving practical tasks; 2.5 points - ("very good") is awarded for knowledge of the educational material above from the average level, including calculations, reasoned answers to the questions questions (a small number of inaccuracies are possible), the ability to apply theoretical ones position during solving practical problems; 2 points - ("good") is awarded for a generally correct understanding of the educational material material, including calculations, reasoned answers to the questions, which, however, contain certain (insignificant) shortcomings, for the ability to apply theoretical ones position during solving practical problems; 1.5 points - ("mediocre") is awarded for mediocre knowledge of the subject material, few well-argued answers, weak application of theoretical provisions when solving practical problems; 1 – ("satisfactory") is awarded for weak knowledge of the educational material component, inaccurate or poorly reasoned answers, with a violation of the sequence presentation, for weak application of theoretical provisions during solving practical tasks; 0.5 point - ("unsatisfactory") is awarded for ignorance of a significant part of the educational material of the component, significant errors in the answers to questions, inability to apply theoretical provisions when solving practical problems.
Recommended books: 1. K.K. Tovstyuk. Electronic educational and methodological complex "Basics of materials science". Vns.lpnu.ua/course/view.php?id=5505 2. K.K. Tovstyuk, I.V. Nychai. study of the structure of crystals by the Debye-Scherer method/ Methodical instructions for performing laboratory work from the course "Fundamentals of Materials Science". Lviv.: NU "Lviv Polytechnic" - 2014 - 10 p. 3. Tovstyuk K.D. Semiconductor materials science. Kyiv.: Naukova dumka, 1984. – 264 p. 2. 4. Smerdov A.A., Dyadenko M.S., Zaichuk V.O., Zakalik L.I., Zinkovskii Y.F. Microelectronics: devices, materials, technology. Kyiv: "Gala". - 1998. - 288 p. 5. Zayachuk D.M. Nanotechnology and nanostructures. Lviv, Publishing House of NU "Lviv Polytechnic", 2009. - 581 p. 6. Mosberg R.K. Material Science - M: Higher School, 1991 - 340 p. 7. Zy. S. Physics of semiconducting devices: Translated from English. / Sub. ed. R.A. Surisa: in 2 volumes. - M.: Mir, 1984. - 320 p. 8. Measurements of non-electric quantities. A.M. Turchyn, P.V. Novitsky, E.S. Levshina and others / Edited by. P.V. Novitskyi. - SktPet.: Energy, 2002 -345 p. 9. Kalinin N.N., Skibinsky G.L., Novikov P.P. Electroradio materials. M.: Vysshaya shkola, 1972.– 300. 8. Kittel Ch. Introduction to Solid State Physics. M.: Science. 1978. – 791 p. 10. Long Ya. O. The magical phenomenon of superconductivity. Lviv.: Euroworld. – 2012 - 440 p. 10. Basics of materials science. Tutorial. Kyiv: GURT Resource Center, 2016. – 101 p. 11. Bialik O.M. and other. Materials science: a textbook / O.M. Bialik, V.S. Chernenko, V.M. Pysarenko, Yu.M. Moskalenko. - K..: IVC "Polytechnic", 2001- 375p