Karta przedmiotu

Experimental Physics - Electromagnetism

Some basic information about the module

Cycle of education:

2012/2013

The name of the faculty organization unit:

The faculty Mathematics and Applied Physics

The name of the field of study:

Engineering Physics

The area of study:

technical sciences

The profile of studing:

The level of study:

first degree study

Type of study:

full time

discipline specialities :

Computer Aided Diagnostics, Ecology of Energy Transformations

The degree after graduating from university:

The name of the module department :

Department of Physics

The code of the module:

524

The module status:

mandatory for teaching programme

The position in the studies teaching programme:

sem: 2, 3 / W45 C45 L30 / 9 ECTS / E,Z

The language of the lecture:

Polish

The name of the coordinator:

Krystyna Chłędowska, PhD

office hours of the coordinator:

wtorek, godz.10.00-11.30, czwartek, godz. 8.30-10.00

The aim of studying and bibliography

The main aim of study:
To introduce students with the basic electrical and magnetic phenomena

The general information about the module:
compulsory module for students in technical physics

Teaching materials:
wykłady w wersji elektronicznej zamieszczane na stronie domowej koordynatora

Bibliography required to complete the module

Bibliography used during lectures
1	C. Bobrowski	Fizyka, krótki kurs	WNT, Warszawa .	1993
2	J. Massalski, M. Massalska	Fizyka dla inżynierów	WNT, Warszawa .	-
3	J. Orear	Fizyka	WNT, Warszawa .	1990
4	R. Resnick, D. Halliday, J. Walker	Podstawy fizyki, t. 3	Wydawnictwo Naukowe PWN Warszawa.	2005

Bibliography used during classes/laboratories/others
1	K. Chłędowska, R. Sikora	Wybrane problemy fizyki z rozwiązaniami, cz. II	Oficyna Wydawnicza PRz, Rzeszów.	2010
2	A. Hennel, W. Krzyżanowski, W. Szuszkiewicz, K. Wódkiewicz	Zadania i problemy z fizyki	PWN, Warszawa .	1993
3	K. Krop, K. Chłędowska	Fizyka, I pracownia	Oficyna Wydawnicza PRz, Rzeszów.	2010

Basic requirements in category knowledge/skills/social competences

Formal requirements:
registration to the second semester of studies

Basic requirements in category knowledge:
calculus, experimental physics: mechanics

Basic requirements in category skills:
calculation of derivatives and integrals, and application of laws of classical mechanics

Basic requirements in category social competences:
ability to work in a small team

Module outcomes

MEK	The student who completed the module	Types of classes / teaching methods leading to achieving a given outcome of teaching	Methods of verifying every mentioned outcome of teaching	Relationships with KEK	Relationships with OEK
MEK01	Knows the quantities characterizing an electrostatic field, Coulomb's law and Gauss's law	lectures, tutorials, laboratory	written exam, test, lab report	K-W009+ K-W017+ K-U005+ K-U009+ K-U015+ K-U016+ K-K006+	T1A-W01+ W03+ InzA-U01+ U01+ U03+ U05+ K01+
MEK02	Knows the basic laws related to flow of electric current	lectures, tutorials, laboratory	written exam, test, lab report	K-W009+ K-W017+ K-U005+ K-U009+ K-U015+ K-U025+ K-U027+ K-K006+	T1A-W01+ W03+ InzA-U01+ U01+ U03+ U05+ U14+ U15+ U16+ K01+
MEK03	able to define the quantities characterizing the magnetic field	lectures, tutorials, laboratory	written exam, test, lab report	K-W009+ K-W017+ K-U005+ K-U009+ K-U015+ K-U025+ K-U027+ K-K006+	T1A-W01+ W03+ U01+ InzA-U01+ U03+ U05+ U14+ U15+ U16+ K01+
MEK04	Knows Maxwell's equations	lectures, tutorials, laboratory	written exam, test, lab report	K-W009+ K-W017+ K-U009+ K-U015+ K-U016+ K-U025+ K-K006+	T1A-W01+ W03+ InzA-U01+ U01+ U03+ U05+ U14+ K01+
MEK05	can describe electric and magnetic properties of matter	lectures, tutorials, laboratory	written exam, test, lab report	K-W009+ K-W017+ K-U009+ K-U015+ K-U016+ K-U025+ K-U027+ K-K006+	T1A-W01+ W03+ InzA-U01+ U01+ U03+ U05+ U14+ U15+ U16+ K01+

The syllabus of the module

Sem.	TK	The content	realized in	MEK
2	TK01	Electric charge. Law of conservation of charge. Coulomb's law. The intensity of the electrostatic field. Electrostatic flux. Gauss' law, examples of applications. Potential fields. Voltage. Work and potential. Potential gradient. Force acting on the surface charge. The energy of the electrostatic field. Energy of the charge systems.	W1-W4, C1-C4, L1-L15	MEK01
2	TK02	Differential form of Gauss' law. Poisson equation. Laplace equation. Conductors in an electrostatic field. Capacity. Electric fields of moving charges.	W5-W6, C5-C6, L1-L15	MEK01
2	TK03	Moments of the charges distribution - monopoly, dipole, quadrupole. Electric dipole in the homogeneous and heterogeneous electric field. Dipole's field - potential and voltage of the field. The energy of two dipoles.	W6-W7, C7-C8, L1-L15	MEK01
2	TK04	Electric current, the current density vector, the equation of continuity. The classic model of electric conductivity. Mobility of charges. Ohm's law in differential form. DC and AC currents. Currents limited electric space charge. Kirchhoff's law. Electromotive force. Temperature dependence of the resistance of metals.	W9, C9, L1-L15	MEK02
2	TK05	Magnetic field. Lorentz force. Biot-Savart Law. Ampere's law in the form of differential and integral. Magnetic vector potential. The phenomenon of electromagnetic induction. Induction currents. Induced emf. Lenz's law. Eddy currents. Mutual inductance, self-induction. The principle of the generator. Maxwell's equations, the Maxwell displacement current.	W10-W13, C10-C14, L1-L15	MEK03 MEK04
2	TK06	Matter in electric and magnetic fields. Dielectric polarization. Electric susceptibility and dielectric permittivity. Clausius-Mossoti equation. Electric induction vector D. Ferroelectrics, electrets, piezo-and piroelectricity. Magnetic dipole moment. Magnetization vector. Magnetic susceptibility. Diamagnetics,	W14-W15, C15, L1-L15	MEK05
3	TK01	Determining the shape of the equipotential surfaces of the electrostatic field	L2-L15	MEK01
3	TK02	Determination of the capacitance and time constant circuit with a capacitor discharge curve	L2-L15	MEK02
3	TK03	Determination of the temperature coefficient of resistance of metals	L2-L15	MEK02
3	TK04	The calibration of thermocouple	L2-L15	MEK02
3	TK05	Verification of the laws of electrolysis Faraday	L2-L15	MEK02
3	TK06	Determination of solenoid inductance and capacitance of the capacitor in an AC circuit	L2-L15	MEK02
3	TK07	Determination of the activation energy of conductivity of semiconductor materials	L2-L15	MEK02
3	TK08	The characteristics of a semiconductor diode	L2-L15	MEK02
3	TK09	Determination of the characteristics of the transistor	L2-L15	MEK02
3	TK10	The study of the magnetic field solenoid	L2-L15	MEK03
3	TK11	Determining the proper charge e / m electron	L2-L15	MEK01 MEK05
3	TK12	Measuring the electron speed by means of the inhibiting voltage	L2-L15	MEK01
3	TK13	Determination of the dielectric permittivity depending on the temperature of the ferroelectric crystals	L2-L15	MEK05

The student's effort

The type of classes	The work before classes	The participation in classes	The work after classes
Lecture (sem. 2)		contact hours: 45.00 hours/sem.
Class (sem. 2)	The preparation for a Class: 30.00 hours/sem. The preparation for a test: 10.00 hours/sem.	contact hours: 45.00 hours/sem.	Finishing/Studying tasks: 30.00 hours/sem.
Advice (sem. 2)		The participation in Advice: 5.00 hours/sem.
Exam (sem. 2)	The preparation for an Exam: 15.00 hours/sem.	The written exam: 2.00 hours/sem.
Laboratory (sem. 3)	The preparation for a Laboratory: 10.00 hours/sem.	contact hours: 30.00 hours/sem.	Finishing/Making the report: 15.00 hours/sem.
Advice (sem. 3)		The participation in Advice: 2.00 hours/sem.
Credit (sem. 3)

The way of giving the component module grades and the final grade

The type of classes	The way of giving the final grade
Lecture	evaluation written examination paper contains theoretical questions, problem and tasks
Class	assessment based on written tests
The final grade
Laboratory	Activity of the student assessed on the laboratory, the theoretical knowledge and the ability to carry out the experiment and properly prepared reports
The final grade	evaluation the average of the ratings of the lecture and tutorials

Sample problems

Required during the exam/when receiving the credit
Untitled 1.pdf

Realized during classes/laboratories/projects
Untitled 2.pdf

Others
(-)

Can a student use any teaching aids during the exam/when receiving the credit : no

The contents of the module are associated with the research profile: no