Data wydruku: 15.01.2017 02:09 Strona 1 z 2 Subject name

Subject name
PHYSICS
Subject code
C:07020IM03
Faculty
Department of Solid State Physics
Course name
Materials Engineering
Learning area
natural sciences
technical sciences
Learning profile
general academic profile
Study year
2
Type of subject
Obligatory
Study semester
3
Study level
undergraduate studies
ECTS
5.0
Number of ECTS
credits
Learning activity of student
ch
Participation in didactic classes included in study plan
60
Participation in consultation hours
sh
5
Self-study hours
60
Sum
Name of lecturer
65
60
Total number of study hours
125
Number of ECTS credits
5.0
dr inż. Jakub Karczewski (Main teacher)
Teachers:
dr inż. Anna Rybicka
dr inż. Jakub Karczewski
Subject objectives
Gaining knowledge of relativistic mechanics, atomic and nuclear physics
Learning outcomes
Mode of delivery
Course outcome
Subject outcome
Method of veryfication
K_U05
The student can learn from
textbooks and scientific literature.
[SU3] Assessment of ability to
use knowledge gained in the
different modules
K_U03
The ability to plan experiments
and analyze the results.
[SU4] Assessment of ability to
use methods and tools
[SU2] Assessment of ability to
analyze information
at the university
Prerequisites
Knowledge from Physics.
Recommended
components
No recommendations
Subject contents
Some problems of relativity: clasical relativity; Lorentz transformations and its consequences; principle of
relativity; mass, momentum, force and energy; space-time. Termal radiation: radiation of black body.
Some problems of atomic physics: photoelectric effect, wave-particle duality; models of atom; Zeeman
effect, Einstein-de Haas experiment, X-ray radiation; lasers. Schrodinger equation, tunneling effect. Some
problems of nuclear physics: binding energy; models of nucleus; nuclear fission; nuclear fusion; nuclear
reactors; passage of radiation through matter.
Recommended
and required
reading
Required reading
1. D. Halliday, R. Resnick, J. Walker „Podstawy fizyki”, t5, PWN
2. A.A. Czerwiński „Energia jądrowa i promieniotwórczość”, OE
3. V. Acosta, C.L. Cowan, B.J. Graham, „Podstawy fizyki współczesnej”
Recommeded reading
1. R.Eisberg, R. Resnick, „Fizyka kwantowa”, PWN
Data wydruku:
08.03.2017 01:53
Strona
1 z 2
Lesson type and
method of
instruction
Lesson type
Number of study hours
Lecture
Tutorial
Laboratory
Project
Seminar
30.0
15.0
15.0
0.0
0.0
Total number of study hours per semester
included in study plan
60
e-learning hours included: 0.0
Assesment
methods and
criteria
Subject passing criteria
Passing threshold
Percentage of the
final grade
Passing experiments
50.0
32.0
written exam
50.0
34.0
Passing exercises
50.0
34.0
Example issues / example questions / tasks being completed
Clasical relativity; Lorentz transformations and its consequences; principle of relativity; mass, momentum,
force and energy; space-time.
Termal radiation: radiation of black body.
Photoelectric effect, wave-particle duality; models of atom; Zeeman effect, Einstein-de Haas experiment,
X-ray radiation; lasers. Schrodinger equation, tunneling effect.
Binding energy; models of nucleus; nuclear fission; nuclear fusion; nuclear reactors; passage of radiation
through matter.
Language of
instructions
Polish
Work placement
Not applicable
Data wydruku:
08.03.2017 01:53
Strona
2 z 2