COURSE SYLLABUS

QUANTUM MECHANICS

1	Course Title:	QUANTUM 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:	9
8	Theoretical (hour/week):	5
9	Practice (hour/week) :	0
10	Laboratory (hour/week) :	0
11	Prerequisites:
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:	Doç. Dr. Mürşide ŞAFAK HACIİSMAİLOĞLU
17	Contactinformation of the Course Coordinator:	malper@uludag.edu.tr
18	Website:
19	Objective of the Course:	To provide students with a basic knowledge of the concepts and applications of quantum mechanics. This course is part one of a two semester course focused on a rigorous exposition to the principles of Quantum mechanics. The Dirac bra-ket formalism will be introduced and used throughout to present the principles of Quantum Mechanics in a general context. We will discuss anyalytic solutions to the Schr¨odinger equation for a variety of potentials in one, two and three dimensions. The role of symmetries as the underlying principle of Quantum Mechanics will be emphasized throughout the course. The use of symmetry principles and operators methods will be discussed
20	Contribution of the Course to Professional Development	Application of the principles of quantum mechanics to unfamiliar problems. To be able to understand easly high technology such as nanotechnology and have leading-ideas to develop hightechnology

Learning Outcomes:

1	Use the superposition principle to predict experimental outcomes for measurement of observables on simple quantum systems. ;
2	Apply the uncertainty principle and heuristic arguments to obtain rough descriptions of quantum systems;
3	Be able to describe generally the physical implications, such as possible bound states and un-bound states for any given hamiltonian.;
4	Derive the eigenkets of the angular momentum operators and prove properties of completeness and orthogonality. ;
5	Learning relations between wave funtions and operatörs and to get information about physical magnitudes using operatörs.;
6	Learning understand and interpretion of advanced technolyg and such as nanotechnology using quantum mechanics.;
7	Learning principals of Quantum technology and applications.;

22	Course Content:

Week	Theoretical	Practical
1	CH1 Why Quantum Mehcanics
2	CH 2: Early Wuantum Theory
3	CH 3: Wave Mechanics
4	CH 3: Wave Packets
5	CH 4: Quantum Motion Equation. Schrödinger Theory
6	CH 5: Stationary States Independent Schrödinger Equationd
7	CH 6: Applicatons of TISE, 1D physical systems, constant potenatials
8	CH 6: Quantum Simple Harmonic Motions-
9	CH 7 Operators in Quantum Mechanics
10	CH 7: Operator and porperties
11	CH 8: Measurement in Quantum Mechanics, Corresponding Principal
12	CH 8: Measurement in Quantum Mechanics, Corresponding Principal
13	CH 9: Atoms with one-electron, Schrödinger Equation
14	CH 10: Angular momentum and Spin, Matrix presantation, pauli spin matrixes.

23	Textbooks, References and/or Other Materials:	1. Prof. Dr. Mürsel ALPER Ders Notları (2020) 2. Bekir Karaoğlu, Kuantum Mekaniğine Giriş 3. Tekin Dereli ve Abdullah Verçin, ODTÜ, Geliştirme Vakfı Yayıncılık ve İletiştim A.Ş. Ankara (1998
24	Assesment

TERM LEARNING ACTIVITIES	NUMBER	PERCENT
Midterm Exam	1	40
Quiz	0	0
Homeworks, Performances	0	0
Final Exam	1	60
Total	2	100
Contribution of Term (Year) Learning Activities to Success Grade		40
Contribution of Final Exam to Success Grade		60
Total		100
Measurement and Evaluation Techniques Used in the Course	The system of relative evaluation is applied.
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