NAME OF THE COURSE |
Physics II |
Code |
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Course teacher |
Assoc Prof Magdy Lučić Lavčević |
Credits (ECTS) |
5.0 |
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Associate teachers |
Lucija Matković |
Type of instruction (number of hours) |
|
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Status of the course |
Mandatory |
Percentage of application of e-learning |
0 % |
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COURSE DESCRIPTION |
Course objectives |
- Introducing students to the knowledge and principles of physics in the fields of electromagnetism, optics and elementary quantum physics - Forming the proper view towards the interpretation of physics phenomena and their application - Developing the level of cognitive processing required for further studies |
Course enrolment requirements and entry competences required for the course |
Enrolled in or passed the course Exercises in Pysics II |
Learning outcomes expected at the level of the course (4 to 10 learning outcomes) |
After the course, the student is expected to have mastered - The principles of electromagnetism and electromagnetic radiation - The principles of geometrical and physical optics - The basic principles of quantum physics - The application of the obtained knowledge in concrete physics examples - The application of the obtained knowledge in solving professional problem tasks - Recognition of the application of the knowledge of physics in everyday situations |
Course content broken down in detail by weekly class schedule (syllabus) |
1st week: Electric charges, electrostatic force and electrostatic field. Vector field flux and Gauss’s law (3 hours). Seminar: Solving the numerical examples pertaining to the theoretical content addressed during the course. (1.5 hours) 2nd week: Electric potential and potential difference. Moving and storing electric charges, electric circuits. (3 hours). Seminar: Solving the numerical examples pertaining to the theoretical content addressed during the course. (1.5 hours) 3rd week: Charges in motion and their interactions, electric current. (3 hours). Seminar: Solving the numerical examples pertaining to the theoretical content addressed during the course. . (1.5 hours) 4th week: Magnetic field. (3 hours). Seminar: Solving the numerical examples pertaining to the theoretical content addressed during the course. (1.5 hours) 5th week: Time depending electric and magnetic fields. Faraday’s law. Inductivity. Induction generators. (3 hours). Seminar: Solving the numerical examples pertaining to the theoretical content addressed during the course. (1.5 hours) Partial assessment (1st preliminary test) related to seminars and theory addressed during the course. 6th week: Alternating currents. Electric machines. (3 hours). Seminar: Solving the numerical examples pertaining to the theoretical content addressed during the course. (1.5 hours) 7th week: Electromagnetic oscillating circuit and radiation. (3 hours). Seminar: Solving the numerical examples pertaining to the theoretical content addressed during the course. (1.5 hours) 8th week: Electromagnetic waves and nature of light. (2 hours). Seminar: Solving the numerical examples pertaining to the theoretical content addressed during the course. (1.5 hours) 9th week: Interaction of electromagnetic radiation and matter: absorption, refraction, reflection, polarization, scattering, photoelectric effect. Ideas of quantum physics. (4 hours). Seminar: Solving the numerical examples pertaining to the theoretical content addressed during the course. (1.5 hours) 10th week: Physical and geometric optics. (3 hours). Seminar: Solving the numerical examples pertaining to the theoretical content addressed during the course (1.5 hours) Partial assessment (2rd preliminary test ) related to seminars and theory addressed during the course |
Format of instruction: |
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Student responsibilities |
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Screening student work (name the proportion of ECTS credits for eachactivity so that the total number of ECTS credits is equal to the ECTS value of the course): |
Class attendance |
0.8 |
Research |
0.0 |
Practical training |
0.0 |
Experimental work |
0.0 |
Report |
0.0 |
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Essay |
0.0 |
Seminar essay |
0.0 |
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Tests |
1.4 |
Oral exam |
1.4 |
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Written exam |
1.4 |
Project |
0.0 |
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Grading and evaluating student work in class and at the final exam |
During the semester, the final exam can be substituted via 2 midterm exams, related to lectures (theory) and seminars (solving problems), according to curriculum. During the final examination period, the final theory exam shall be taken after passing the final problem´s solving exam. Grades: 55-64% - sufficient; 65-79% - good, 80-89% - very good; 90-100% - excellent |
Required literature (available in the library and via other media) |
Title |
Number of copies in the library |
Availability via other media |
N. Cindro, Fizika II, Školska knjiga, Zagreb, 1985. |
10 |
|
E. Babić, R. Krsnik, M. Očko, Zbirka riješenih zadataka iz fizike, Školska knjiga, Zagreb, Zagreb, 1990. |
3 |
|
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Optional literature (at the time of submission of study programme proposal) |
D. Halliday, R. Resnick, Fundamentals of Physics, John Wiley, New York 2003. Janko Herak, Osnove kemijske fizike, Farmaceutsko-biokemijski fakultet Sveučilišta u Zagrebu, 2001. V. Lopac, P. Kulišić, M. Pavičić, Zbirka zadataka iz fizike, FGZ Zagreb, 1983.
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Quality assurance methods that ensure the acquisition of exit competences |
Quality assurance will be performed at three levels: (1) University Level; (2) Faculty Level by Quality Control Committee; (3) Lecturer’s Level. |
Other (as the proposer wishes to add) |
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