22ZP113 - Technical physics 2
| Course specification | ||||
|---|---|---|---|---|
| Course title | Technical physics 2 | |||
| Acronym | 22ZP113 | |||
| Study programme | Biochemical Engineering and Biotechnology,Environmental Engineering,Material Engineering,Metallurgical Enginering | |||
| Module | Material Engineering | |||
| Lecturer (for classes) | ||||
| Lecturer/Associate (for practice) | ||||
| Lecturer/Associate (for OTC) | ||||
| ESPB | 6.0 | Status | ||
| Condition | none | Облик условљености | ||
| The goal | The course was designed to provide fundamental knowledge in the field of modern physics, which had an undeniable influence on the development of new engineering and scientific disciplines. Students are introduced to basic concepts in electrostatics, stationary electric currents, electromagnetism, electromagnetic oscillations and electromagnetic waves, geometric optics, wave optics, photometry, atomic physics, nuclear physics, and quantum physics. | |||
| The outcome | Introducing students to physical laws and phenomena relevant to engineering practice. Developing the necessary analytical abilities for the application of physical laws in understanding and solving engineering problems. | |||
| Contents | ||||
| Contents of lectures | Electrostatics. Coulombs’ law. Electric field strength vector. Field potential. Gauss's Law. Electrostatic induction. Conductors in the electrostatic field. Dielectrics in electrostatic field and polarization of dielectrics. Electrical capacitance. Energy in the electrostatic field. Stationary electric current. Electricity in metals. Kirchhoff's Laws. Specific electrical conductivity and specific resistance. Current in liquids, gases and vacuum. Contact and thermoelectric phenomena. Electromagnetism. Stationary magnetic field. Biot-Savart Law. Magnetic flux. Amper’s Law and general Amper's Law. Magnetic properties of substances. Magnetic circuits.Electromagnetic induction. Faraday's Law.Mutual inductance and self-inductance. Energy in a magnetic field. Electromagnetic oscillations and electromagnetic waves. Oscillator circuits. Properties of electromagnetic waves. Poynting vector.Maxwell equations. Optics. Basic laws of geometric optics. Behavior of light on a flat and spherical boundary of homogeneous environments. Ferma and Heigens' principle. Absorption, dispersion and scattering of light. Lens. Advantages and disadvantages. Optical instruments. Photometry. Wavelength properties of light. Interference, diffraction and polarization of light. Stimulated radiation. Atomic physics. Quantum nature of electromagnetic radiation. X-rays. Radiation laws. Interaction of radiation with matter: photoelectric effect, Compton’s effect and pair production. Zeeman effect. Nuclear physics… | |||
| Contents of exercises | Laboratory practices 1) Determination of resistance of thermogenic resistors using Wheatstone bridge 2) Determination of the temperature coefficient of electrical resistance of metals 3) Determination of the parameters of the electrical circuit by measuring the intensity of the current (Om's law) 4) Determination of the power of a thermoset 5) Determination of refractive index of window glass using a microscope 6) Determination of the focal length of the collecting and dissipation lens 7) Determination of wavelength of light by Newton's rings 8) Determination of wavelength of light by diffraction grating 9) Determination of the absorption coefficient of the substance for gamma radiation 10) The law of radioactive decay | |||
| Literature | ||||
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| Number of hours per week during the semester/trimester/year | ||||
| Lectures | Exercises | OTC | Study and Research | Other classes |
| 3 | 1.6 | 1.4 | ||
| Methods of teaching | Theoretical lectures, practical lectures, laboratory practical | |||
| Knowledge score (maximum points 100) | ||||
| Pre obligations | Points | Final exam | Points | |
| Activites during lectures | Test paper | 50 | ||
| Practical lessons | 5 | Oral examination | ||
| Projects | ||||
| Colloquia | 45 | |||
| Seminars | ||||