PAÜ .:. Eğitim Öğretim Bilgi Sistemi

COURSE INFORMATION

Course Code	Course Title	L+P Hour	Semester	ECTS
FIZ 343	INTRODUCTION TO QUANTUM PHYSICS	4 + 0	6th Semester	6

COURSE DESCRIPTION

Course Level	Bachelor's Degree
Course Type	Compulsory
Course Objective	The aim is to teach the fundamentals of quantum theory which is valid in the microscopic world.
Course Content	Origins of Quantum Physics, Postulates of Quantum Mechanics, One-Dimensional Problems, Mathematical Tools of Quantum Mechanics
Prerequisites	No the prerequisite of lesson.
Corequisite	No the corequisite of lesson.
Mode of Delivery	Face to Face

COURSE LEARNING OUTCOMES

1	Events causing the birth of quantum physics are learnt.
2	Postulates of quantum mechanics are learnt.
3	Schrödinger equation is solved for some simple examples in one diemension.

COURSE'S CONTRIBUTION TO PROGRAM

ECTS ALLOCATED BASED ON STUDENT WORKLOAD BY THE COURSE DESCRIPTION

Activities	Quantity	Duration (Hour)	Total Work Load (Hour)
Course Duration (14 weeks/theoric+practical)	14	4	56
Hours for off-the-classroom study (Pre-study, practice)	14	4	56
Assignments	3	8	24
Mid-terms	1	10	10
Final examination	1	10	10
Total Work Load ECTS Credit of the Course			156 6

COURSE DETAILS

Select Year

Course Details

Course Code	Course Title	L+P Hour	Course Code	Language Of Instruction	Course Semester
FIZ 343	INTRODUCTION TO QUANTUM PHYSICS	4 + 0	1	Turkish	2023-2024 Spring

Course Coordinator	E-Mail	Phone Number	Course Location	Attendance
Assoc. Prof. Dr. ASLI ÖZTÜRK KİRAZ	aslio@pau.edu.tr		FEN B0211	%60

Goals		The aim is to teach the fundamentals of quantum theory which is valid in the microscopic world.
Content		Origins of Quantum Physics, Postulates of Quantum Mechanics, One-Dimensional Problems, Mathematical Tools of Quantum Mechanics

Topics

Weeks	Topics
1	Born of Quantum Physics, Atom Models
2	Particle-wave duality, wave packet, Heisenberg uncertainty principle.
3	Schrödinger wave equation, The Rewiev of the Probability interpretation of wave functions.
4	Motion in two dimension, The concept of operator, Expectation values, Momentum space, Problem solutions.
5	Time independent Schrödinger equation, plane wave solutions of free particle, Dirac-delta function.
6	Step potential, Potential barrier, tunneling effect.
7	Infinite potential well, rectangular potential barrier.
8	Harmonic oscillator.
9	Quantum Physics Postulas
10	Wave function space, Matrix description of Linear Operators.
11	Investigation of many body systems in one dimension space.
12	Schrödinger Wave Function in three dimension space.
13	Angular Momentum
14	Hydrogen Atom

Materials

Materials are not specified.

Resources

Resources	Resources Language
'Kuantum Fiziğine Giriş', Prof. Dr. Mustafa Dikici, Seçkin Kitabevi.	Türkçe
‘Kuantum Mekaniğine Giriş’ Bekir Karaoğlu, Seçkin Yayınevi.	Türkçe
‘Kuantum Fiziği I’, Prof. Dr. Abdulhalik Karabulut, Prof.Dr. Gökhan Budak, Nobel Yayınevi.	Türkçe
‘Fenciler için Kuantum Mekaniği’, Prof. Dr. Fevzi Köksal, Dr. Rahmi Köseoğlu, Nobel Yayınevi.	Türkçe
‘Modern Quantum Mechanics’, J. J. Sakurai, Addison-Wesley.	English
‘Quantum Mechanics’, L. Ballentine, World Scientific.	English
‘Kuantum Mekaniğine Giriş’ Bekir Karaoğlu, Seçkin Yayınevi.	Türkçe

Course Assessment

Assesment Methods	Percentage (%)	Assesment Methods Title
Final Exam	50	Final Exam
Midterm Exam	50	Midterm Exam

L+P: Lecture and Practice
PQ: Program Learning Outcomes
LO: Course Learning Outcomes

Prospective Student