1. FIRST CYCLE - BACHELOR'S DEGREE
  2. FACULTY OF EDUCATION
  3. EDUCATION OF SCIENCE AND MATHEMATICS DEPARTMENT
  4. 117 ELEMENTARY SCIENCE EDUCATION
Course Information Course Learning Outcomes Course's Contribution To Program ECTS Workload Course Details
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COURSE INFORMATION
Course CodeCourse TitleL+P HourSemesterECTS
FBO 2104PHYSICS 42 + 04th Semester3

COURSE DESCRIPTION
Course Level Bachelor's Degree
Course Type Compulsory
Course Objective The aim of this course is to provide the student with the scope of Modern Physics, which explains the events and phenomena at microscopic scale and at speeds close to the speed of light, which Classical Physics is insufficient to explain.
Course Content Relativity: Principles of Galilean Relativity, Michelson-Morley experiment, Einstein's principle of relativity, results of special relativity (time dilation, simultaneity, length contraction, twin paradox), Lorentz Transformation Equations, Relative linear momentum, relativistic energy, General theory of relativity. Quantum Physics: Blackbody radiation and Planck's hypothesis, Photoelectric effect, Compton Effect, Nature of Electromagnetic Waves, Wave properties of particles, Quantum particle model, Double slit experiment, Uncertainty Principle. Quantum Mechanics: Wave function, Quantum particle under boundary conditions, Schrödinger Equation , Particle in a finite height well, Tunneling in a potential barrier, applications of tunneling, Simple Harmonic Vibrator. Atomic Physics: Atomic spectrum in gases, Early models of the atom, Bohr Model of hydrogen atom, Quantum model of hydrogen atom, Wave functions for hydrogen, Physical interpretation of quantum numbers, The Exclusion Principle and the Periodic Table, A more detailed look at atomic spectra, Spontaneous and excited transitions, Lasers. Molecule Physics: Molecular bonds, Energy levels and spectra of molecules, Bonding in solids, Free electron theory of metals, Band theory of solids, Electrical conductivity in metals, insulators and semiconductors, semiconductor devices, Superconductivity. Nuclear Physics: Some properties of atomic nuclei, Nucleus binding energy, Nuclear models, Radioactivity, Decay processes, Natural radioactivity, Nuclear reactions, Nuclear Magnetic Resonance and Magnetic Resonance Imaging. Applications of Nuclear Physics: Interactions involving Neutrons, Nuclear fission, Nuclear reactors, Nuclear fusion (fusion), Radiation damages, Uses of radiation. Particle Physics and Cosmology: Fundamental forces in nature, Positrons and other antiparticles, Mesons and an introduction to particle physics , Classification of particles, Conservation laws, Strange particles and strangeness, Patterns of presence in particles, Quarks, Multicolored quarks, Standard model, Cosmic connection, problems and perspectives.
Prerequisites No the prerequisite of lesson.
Corequisite No the corequisite of lesson.
Mode of Delivery Face to Face

COURSE LEARNING OUTCOMES
1Expresses the principles of Special Relativity and General Relativity, and indicates its results and effects.
2Explains how quantum approaches overcome these inadequacies by stating the inadequacies in classical physics that prepared the birth of quantum physics.
3Expresses the basic principles of quantum mechanics by explaining how quantum mechanics succeeds instead of classical mechanics, which fails to analyze the behavior of particles and systems at the microscopic scale.
4Explain the development of atomic models and explain the modern quantum atom model.
5Explains the band theory in solids by revealing the bond types and molecular energy levels of molecules.
6Defines core models by explaining core binding energy.
7Describes the decay processes by explaining radioactivity.
8Explains the usage areas of radiation by explaining the Fission Fusion reactions within the scope of applications of nuclear physics.
9Explain the fundamental forces and subatomic particles in nature.

COURSE'S CONTRIBUTION TO PROGRAM
PO 01PO 02PO 03PO 04PO 05PO 06PO 07PO 08PO 09PO 10PO 11PO 12PO 13
LO 0015    4  4  5 
LO 00254  44  3    
LO 00354  35  4 5  
LO 00453  44  5 44 
LO 00554  34  4 4  
LO 00653  53  4 4  
LO 00754  44  4    
LO 0085            
LO 00944  43  4 4  
Sub Total4426  2731  32 219 
Contribution5300330040210

ECTS ALLOCATED BASED ON STUDENT WORKLOAD BY THE COURSE DESCRIPTION
ActivitiesQuantityDuration (Hour)Total Work Load (Hour)
Course Duration (14 weeks/theoric+practical)14228
Hours for off-the-classroom study (Pre-study, practice)14228
Mid-terms11111
Final examination11111
Total Work Load

ECTS Credit of the Course





78

3
COURSE DETAILS
 Select Year   


 Course TermNoInstructors
Details 2023-2024 Spring1İSMAİL UYSAL
Details 2023-2024 Spring2İSMAİL UYSAL


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Course Details
Course Code Course Title L+P Hour Course Code Language Of Instruction Course Semester
FBO 2104 PHYSICS 4 2 + 0 1 Turkish 2023-2024 Spring
Course Coordinator  E-Mail  Phone Number  Course Location Attendance
Asts. Prof. Dr. İSMAİL UYSAL iuysal@pau.edu.tr EGT A0132-11 %70
Goals The aim of this course is to provide the student with the scope of Modern Physics, which explains the events and phenomena at microscopic scale and at speeds close to the speed of light, which Classical Physics is insufficient to explain.
Content Relativity: Principles of Galilean Relativity, Michelson-Morley experiment, Einstein's principle of relativity, results of special relativity (time dilation, simultaneity, length contraction, twin paradox), Lorentz Transformation Equations, Relative linear momentum, relativistic energy, General theory of relativity. Quantum Physics: Blackbody radiation and Planck's hypothesis, Photoelectric effect, Compton Effect, Nature of Electromagnetic Waves, Wave properties of particles, Quantum particle model, Double slit experiment, Uncertainty Principle. Quantum Mechanics: Wave function, Quantum particle under boundary conditions, Schrödinger Equation , Particle in a finite height well, Tunneling in a potential barrier, applications of tunneling, Simple Harmonic Vibrator. Atomic Physics: Atomic spectrum in gases, Early models of the atom, Bohr Model of hydrogen atom, Quantum model of hydrogen atom, Wave functions for hydrogen, Physical interpretation of quantum numbers, The Exclusion Principle and the Periodic Table, A more detailed look at atomic spectra, Spontaneous and excited transitions, Lasers. Molecule Physics: Molecular bonds, Energy levels and spectra of molecules, Bonding in solids, Free electron theory of metals, Band theory of solids, Electrical conductivity in metals, insulators and semiconductors, semiconductor devices, Superconductivity. Nuclear Physics: Some properties of atomic nuclei, Nucleus binding energy, Nuclear models, Radioactivity, Decay processes, Natural radioactivity, Nuclear reactions, Nuclear Magnetic Resonance and Magnetic Resonance Imaging. Applications of Nuclear Physics: Interactions involving Neutrons, Nuclear fission, Nuclear reactors, Nuclear fusion (fusion), Radiation damages, Uses of radiation. Particle Physics and Cosmology: Fundamental forces in nature, Positrons and other antiparticles, Mesons and an introduction to particle physics , Classification of particles, Conservation laws, Strange particles and strangeness, Patterns of presence in particles, Quarks, Multicolored quarks, Standard model, Cosmic connection, problems and perspectives.
Topics
WeeksTopics
1 Relativity: Principles of Galilean Relativity, Michelson-Morley experiment, Einstein's principle of relativity, results of special relativity (time dilation, simultaneity, length contraction, twins paradox), ...
2 Relativity: … Lorentz Transformation Equations, Relative linear momentum, relativistic energy, General theory of relativity.
3 Quantum Physics: Blackbody radiation and Planck's hypothesis, Photoelectric effect, Compton Effect, Nature of Electromagnetic Waves, Wave properties of particles, Quantum Particle model, Double slit experiment, Uncertainty Principle.
4 Quantum Mechanics: Wave function, Quantum particle under boundary conditions, Schrödinger Equation, Particle in a well of finite height, Tuning in a potential barrier, applications of tunneling, Simple Harmonic Vibrator.
5 Atomic Physics: Atomic spectrum in gases, first models of the atom, Bohr Model of the Hydrogen atom, Quantum model of the Hydrogen atom, Wave functions for Hydrogen, …
6 Atom Fiziği : … Kuantum sayılarının fiziksel yorumu, Dışarılama İlkesi ve Periyodik Tablo, Atom,k spektrumlara daha detaylı bir bakış, Kendiliğinden ve uyarılmış geçişler, Laserler
7 Molecular Physics: Molecular bonds, Energy levels and spectra of molecules, Bonding in solids, Free electron theory of metals, …
8 Molecular Physics: ...Band theory of solids, Electrical conductivity in metals, insulators and semiconductors, semiconductor devices, Superconductivity
9 Nuclear Physics: Some properties of atomic nuclei, Nucleus binding energy, Nucleus models,..
10 Nuclear Physics: … Radioactivity, Decay processes, Natural radioactivity, Nuclear reactions, Nuclear Magnetic Resonance and Magnetic Resonance Imaging.
11 Applications of Nuclear Physics: Interactions involving neutrons, Nuclear fission, Nuclear reactors, …
12 Applications of Nuclear Physics: ... Nuclear fusion, Radiation damage, Uses of radiation.
13 Particle Physics and Cosmology: Fundamental forces in nature, Positrons and other antiparticles, Mesons and introduction to particle physics, Classification of particles, …
14 Particle Physics and Cosmology: …Conservation laws, Strange particles and strangeness, Patterns of presence in particles, Quarks, Multicolored quarks, Standard model, Cosmic connection, problems and perspectives.
Materials
Materials are not specified.
Resources
ResourcesResources Language
Fen ve Mühendislik İçin Fizik III, Modern Fizik, Serway & Beichner, Palme YayıncılıkTürkçe
Course Assessment
Assesment MethodsPercentage (%)Assesment Methods Title
Final Exam60Final Exam
Midterm Exam40Midterm Exam
L+P: Lecture and Practice
PQ: Program Learning Outcomes
LO: Course Learning Outcomes