Dec 15, 2019   7:46 p.m. Ivica
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Course syllabus AFYZ01_6I - Applied Physics (MTF - WS 2020/2021)

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University: Slovak University of Technology in Bratislava
Faculty: Faculty of Materials Science and Technology in Trnava
Course unit code: AFYZ01_6I
Course unit title: Applied Physics
Mode of delivery, planned learning activities and teaching methods:
lecture2 hours weekly / 26 hours per semester of study (on-site method)
26 hours per semester of study (combined method)
seminar2 hours weekly / 26 hours per semester of study (on-site method)
26 hours per semester of study (combined method)

Credits allocated: 5
Recommended semester/trimester: -- item not defined --
Level of study: 2.
Prerequisites for registration: none
Assesment methods:
student can be awarded max. 20% during semester. This can be accomplished by written exam (max. 2 times). The final examination starts with the written part, that is worth up to 80 %. The exam can be carried out in written form, oral form or by combination of both.The final evaluation of the exam is composed by total points acquired during semester and the written part of final examination. For the grade A at least 92 points in total are necessary. For the grade B at least 83 points in total are necessary. For the grade C at least 74 points in total are necessary. For the grade D at least 65 points in total are necessary, and for the grade E at least 56 points. No credits will be given to the student failing to reach at least 56 points in total.
Learning outcomes of the course unit:
The knowledge obtained in physics and related subjects during the bachelor stage will be broadened and improved to the level at which the student will be able to develop engineering answers to technical problems. Theoretical understanding and practical skills in physics will allow him to develop creative solutions for complex engineering problems.
Course contents:
1.electromagnetic radiation(spectrum,wave equation, priciples of optics, interfence, diffraction, X-ray diffraction on crystal planes, radiation of black body, photons)
2.basics of quantum and statistical physics needed to understand the connection between electronic structure and properties of materials( energy quantisation,Schrodinger equation, band theory of solids,spin, Boltzman statistics,statistics of fermions and bosons, electrical conductivity, electrical rezistance, electrical properties of materials, piesoelectricity,magnetic properties of materials)
3.Electron beam( generation of Electron beam, properties, Lorentz force, electrons in electromagnetic field, control of electron beam, interaction of the Electron beam with materials, technological applications using electron beam
4.Diffusion and transport of heat in materials( physical basis of diffusion, I. and II.Fics law, equation of heat transfer, diffusion and heat transfer in technological processes and welding of materials
5.Laser welding( principles of laser radiation, characteristics of laser beam,lasers used in technological applications, basic parameters of the laser beam and their measurements, interaction od laser with materials)
6.Electric arc( generation of the electric arc, characteristics of the electric arc, cathodic region. anodic region,arc column, VA characterists of electric arc, heat balance,applications of the electric beam in technological processes
7. plasma arc( generation of the plasma arc, characteristics of the plasma arc, influence of the plasma gas on the final properties of the plasma arc, application of the plasma arc in technological processes
8.Electromagnetic induction(priciples, induction heating, technological processes using induction heating
9.friction( physical principles of friction, constant of friction, sliding friction, energy of friction, rolling friction, internal friction,utilization of friction in technological processes
10.Oscillations of mechanical systems( linear and non-linear systems,resonance in both linear and non-linear systems
11.Ultrasound ( generation of ultrasound waves,characteristic properties of ultrasound,propagation of ultrasound in materials, transformation of ultrasound energy into heat, application of ultrasound in production technologies
Recommended or required reading:
BEISER, A. -- ČADA, J. Úvod do moderní fyziky. Praha : Academia, 1978. 628 p.
HALLIDAY, D. -- RESNICK, R. -- WALKER, J. Fyzika: Vysokoškolská učebnica obecné fyziky. Z angl.orig. Brno : VUTIUM, 2000. 1198 p. ISBN 80-214-1869-9.
KREMPASKÝ, J. Fyzika. Bratislava: Alfa, 1992. 751 p.
KREMPASKÝ, J. Fyzika: Základný kurz pre technické univerzity. Bratislava : Alfa, 1992. 503 p. ISBN 80-05-01063-X.
BARTA, Š. Fyzika dynamických procesov. Bratislava : STU v Bratislave, 2002. 160 p. ISBN 80-227-1680-4.
BARTA, Š. -- DIEŠKA, P. Fyzika tuhých látok 1. Bratislava : STU v Bratislave, 1993. 281 p.
BARTA, Š. Fyzika tuhých látok 2. Bratislava : STU v Bratislave, 1991. 240 p.
HALLIDAY, D. -- RESNICK, R. -- WALKER, J. Fundamentals of physics extended. New York : John Wiley & Sons, 1997. 1142 p. ISBN 0-471-10559-7.
FEYNMAN, R P. -- LEIGHTON, R B. -- SANDS, M. Feynmanovy přednášky z fyziky s řešenými příklady 1/3. Havlíčkův Brod : Fragment, 2000. 732 p. ISBN 80-7200-405-0.
FEYNMAN, R P. -- LEIGHTON, R B. -- SANDS, M. Feynmanovy přednášky z fyziky s řešenými příklady 2/3. Havlíčkův Brod : Fragment, 2001. 806 p. ISBN 80-7200-420-4.

Language of instruction: slovak or english
Courses evaluation:
Assessed students in total: 993

6,6 %12,1 %18,1 %22,8 %38,3 %2,1 %
Name of lecturer(s): prof. Ing. Marian Kubliha, PhD. (examiner, instructor)
prof. Ing. Ján Lokaj, PhD. (examiner, instructor, lecturer, person responsible for course) - slovak, english
RNDr. Peter Perichta, CSc. (examiner, instructor)
Last modification: 15. 8. 2019
Supervisor: prof. Ing. Ján Lokaj, PhD. and programme supervisor

Last modification made by Ing. Erika Kuracinová on 08/15/2019.

Type of output: