COURSE SYLLABUS

QANTUM MECHANICS

1	Course Title:	QANTUM MECHANICS
2	Course Code:	FZK3002
3	Type of Course:	Compulsory
4	Level of Course:	First Cycle
5	Year of Study:	3
6	Semester:	6
7	ECTS Credits Allocated:	8
8	Theoretical (hour/week):	5
9	Practice (hour/week) :	0
10	Laboratory (hour/week) :	0
11	Prerequisites:	Fundamental Physics, Classical Mechanics, Waves, Physical Mathematics
12	Recommended optional programme components:	None
13	Language:	Turkish
14	Mode of Delivery:	Face to face
15	Course Coordinator:	Prof. Dr. Mürsel Alper
16	Course Lecturers:	Yrd. Doç. Dr. Mürşide ŞAFAK HACIİSMAİLOĞLU
17	Contactinformation of the Course Coordinator:	malper@uludag.edu.tr, (0224) 29 41 697, UÜ Fen Edebiyat Fakültesi, Fizik Bölümü 16059 Görükle Kampüsü Bursa
18	Website:
19	Objective of the Course:	To study the behaviour and physics of microscopic particles such as atoms, molecules, electrons and protons). To learn Quantum Motion Equation and applying to the behaviour of quantum particles. To gain the capabilities to be able to understand micro- and nanotechnology
20	Contribution of the Course to Professional Development

Learning Outcomes:

1	To understand the difference between classical and Quantum mechanics.;
2	To know both light and matter always may have the dual nature;
3	To know an uncertainty is in the quantum mechanical magnitudes and all measurements is expressed in probabilities;
4	To learn a quantum particle must be presented by a wave function as ‘ the state definition’;
5	To learn how physical information is obtained from wave functions;
6	To solve the Scrödinger equation to study the behaviour of a microscopic particle;
7	To learn the relationship between operators and physical observables.;
8	To solve the Schrödinger Equation to study the nature of an atom and its physical properties;
9	To gain the capabilities to be able to understand micro- and nanotechnology;
10	To understand the technological applications of quantum mechanics;

22	Course Content:

Week	Theoretical	Practical
1	Why Quantum Physics, Early Quantum Theories
2	Wave Mechanics, Wave Function, and its interpretation
3	Wave Packets, Expectation Values
4	Quantum Motion Equation (Time-Dependent Schreodinger Equation)
5	Probability Fluid, Probability Flux Density
6	Stationary Physical Systems
7	Solutions to Schroedinger Equation Midterm exam 1,
8	Time-Independent Schrödinger Equation and its Applications
9	Quantum Simple Harmonic Motion
10	Operators in Quantum Mechanics
11	Applications of Operators, Operator Cebric Techniques
12	Correspondence Principle and Measurements Midterm exam 2
13	Atoms with One Electron with The Schrödinger Theory
14	Angular Momentum, Matrix Mechanics

23	Textbooks, References and/or Other Materials:	1. M. ALPER, Kuantum Mekaniği Ders Notları 2. Bekir Karaoğlu, Kuantum Mekaniğine Giriş, Seçkin Yayıncılık, 2008, Ankara 3. Tekin Dereli, Abdullah Verçin, Kuantum Mekaniği I, ODTÜ yayınları, 1998, Ankara
24	Assesment

TERM LEARNING ACTIVITIES	NUMBER	PERCENT
Midterm Exam	2	50
Quiz	0	0
Homeworks, Performances	0	0
Final Exam	1	50
Total	3	100
Contribution of Term (Year) Learning Activities to Success Grade		50
Contribution of Final Exam to Success Grade		50
Total		100
Measurement and Evaluation Techniques Used in the Course
Information

ECTS / WORK LOAD TABLE

CONTRIBUTION OF LEARNING OUTCOMES TO PROGRAMME QUALIFICATIONS

LO: Learning Objectives

PQ: Program Qualifications

Contribution Level:

1 Very Low

2 Low

3 Medium

4 High

5 Very High