GRADUATE COURSE DETAILS Course title :...

GRADUATE COURSE DETAILS

Course title : QUANTUM MECHANICS I

Code : FFZ 5103

Institute: Science Field: Physics

Education and Teaching Methods Credits Lecture Application Laboratuary Project/

Field Study Homework

Other Total T+A+L=Credit

ECTS

14x3=42 - - - 5x14= 70 14x5=70 200 3 8

Semester Autumn Language Turkish/English

Course Type

Basic Scientific

Scientific Technical Elective

Social Electrive

Course Objectives

The aim of the course is to introduce quantum mechanics in the graduate level.

Learning Outcomes and Competences

To calculate ground state physical properties of a single particle under simple potentials using Dirac’s formalism, To determine the space and time propagation for a free particle, To add two angular momenta and make connection to Wigner-Eckart theorem.

Textbook and /or References

[1] J.J. Sakurai “Modern Quantum Mechanics”, Addison-Wesley, 1994 [2] Other quantum mechanics books in graduate level

ASSESSMENT CRITERIA

Theoretical Courses Project Course and Graduation Study

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mark as (X)

Percent (%)

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Midterm Exams Midterm Exams

Quizzes Midterm Controls

Homeworks X 40 Term Paper

Term Paper (Projects,reports, ….)

Oral Examination

Laboratory Work Final Exam

Final Exam X 60 Other

Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Dirac formalism; Measurements, observables and uncertainty relations Change of basis; Position, momentum and translation operators Wave functions in momentum and position spaces Time evolution operator and the Schrodinger equation The Schrodinger and the Heisenberg picture Simple harmonic oscillator Propagators and Feynman Path integrals Potentials and Gauge transformations Angular momentum and Pauli two-component formalism Eigenvalues and eigenstates of angular momentum; Orbital angular momentum Angular momentum addition and Clebsch-Gordan coefficients Tensor operators and the Wigner-Eckart theorem Symmetries and conservation laws Parity, space inversion, lattice translation, time reversal

Instructors Assoc. Prof. Ali TEKE

E-mail [email protected]

Web Address w3.balikesir.edu.tr/ateke


Course title : Advance Atomic Physics

Code : FFZ 5104





ECTS

14x3=42 0 0 - 5x14= 70 14x5=70 200 3 8


Course Type

Basic Scientific Scientific

Technical Elective

Social Electrive

Course Objectives

Introduction to atomic physics and its applications


1) To solve the Schrödinger Equation for hydrogen atom 2) To solve the Schrödinger Equation for atoms with many electrons 3) To learn fine and hyperfine structures and their application 4) To learn Periodic table and their classification 5) To learn atom models 6) To learn the investigation of atoms with electromagnetic waves 7) To learn X-ray spectroscopy


[1] Atom ve Molekül Fiziği , B. H. Bransden C.J. Joachain, Translate editor: Prof. Dr. Fevzi Köksal 1989, Samsun University [2] Atom ve Molekul Fizigi, Erol Aygun, Mehmet Zengin, Bizim Büro, Ankara. [3] Modern Fiziğin Kavramları, Arthur Beiser, Çeviren: Gülsen Önengüt, Akademi yayıncılık, Ankara. [4] Atomlar ve Moleküller, M.Ayhan Zeren, Birsen Yayınevi.

ASSESSMENT CRITERIA


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Midterm Exams X 30 Midterm Exams

Quizzes X 5 Midterm Controls



Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Atomic physics and Applications Atom with a single electron, Eigenvalue, Eigenfunction, Schrödinger Equation and it’s solution Fine structure, hyper fine structure Interaction of atoms with electric and magnetic electromagnetic waves Atom with two electrons and Schrödinger Equation Atoms with many electrons Central field approximation Periodic Table Thomas-Fermi atom model Hartree Fock method L-S and J-J kubling Interaction of Atoms with many electrons of electromagnetic waves X-Ray Spectroscopy Perturbation in atomic physics and its applications

Instructors Prof. Dr. Rifat ÇAPAN


Web Address w3.balikesir.edu.tr/rcapan


Course title: Langmuir-Blodgett Thin Film Technology I

Code: FFZ 5109


Education and Teaching Methods Credits Lecture Application Laboratory Project/



ECTS

14x3=42 0 0 - 5x14= 70 14x5=70 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To introduce the Langmuir-Blodgett thin films and the produce of LB films and applications


1) To learn LB film materials and properties 2) To learn applications of LB film materials 3) To understand phase transition and isotherm graphs 4) To understand multilayer LB thin and their applications


[1] Langmuir-Blodgett Films, Michael C. Petty, 1996, CambridgePress. [2] Langmuir-Blodgett Films, by G. Roberts, 1990, Springer, New York. [3] An Introduction to Ultra thin Organic Films: From Langmuir-Blodgett to Self-Assembly, A. Ulman, 1991, Academic Pres.

ASSESSMENT CRITERIA


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Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

An introduction to Langmuir-Blodgett (LB) film Technology LB film materials and its properties Applications of LB film materials LB film equipments Phase transition of materials at the water surface Solid, Liquid, gas phases and collapse Investigation of monolayer at the water surface Isotherm graphs Calculation of surface area Monolayer LB films Multilayer LB films Alternate Layer LB films Defects of LB films Applications of LB films





Course Title: ADVANCED NUCLEAR PHYSICS

Code: FFZ 5110 Institute: Science Field: Physics

Education and Teaching Methods Credits Lecture Applicati

on Laboratuary Project/

Field Study Homework Other Total T+A+L=

Credit ECTS

14x3=42 0 0 - 5x14= 70 14x5=70 200 3 8


Course Type


Technical Elective

Social Elective

Course Objectives

To learn the nuclei structure with detailed


To learn the nuclear properties, To learn the nuclear force properties, To learn the nuclear models, To learn alpha decay, To learn beta decay


The Atomic Nucleus R.D. EVANS Mc-Graw-Hill, 1955. Nuclear Physics I. KAPLAN Addison-Wesley Company, 1962. Nuclear Physics W.E. BURCHAM Logman G. U. ,1973. Introductory Nuclear Physics K.S. Krane, J.Willey&Sons Inc.,1988.

ASSESSMENT CRITERIA


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Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Properties of Nuclei “ “ Nuclear Moments, Parity and Statistics Nuclear Effects in Spectroscopy Systematic of Stable Nuclei Models of Nuclei “ “ Forces Betweens Nucleons “ “ Dynamical Properties of Nuclei Nuclear Reactions “ “ Alpha Ray-Spectra Beta Ray-Spectra

Course Teacher Prof. Dr. ASUMAN AYDIN

e-mail [email protected]

Web Address w3.balikesir.edu.tr/aydina


Course title : : Mathematical Methods in Physics I

Code : FFZ 5111


Education and Teaching Methods Credits Lecture Applicatio

n Laboratuary Project/

Field Study Homework Other Total T+A+L=C

redit ECTS

14x3=42 0 0 5x14= 70 14x5=70 200 3 8


Course Type

Basic Scientific


Social Electrive

Course Objectives

Development and Applications of Mathematical Postulates In Order to Solve the Theoretical Physics Problems


Knowlege and Application of Mathematical Tolls to Physical Problems


[1] Mathematical Methods for Physicsist , George Arfken, Academic Press [2] Mathematical Physics, Eugene Butkov, Addison Wesley [3] Fen ve Mühendislik Bilimlerinde Matematik Yöntemler, Selçuk Bayın, Metu Press

ASSESSMENT CRITERIA


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mark as (X)

Percent (%)

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Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Complex Functions and Complex Algebra, Cauchy-Reimann Conditions, Cauchy Integral Theory Laurent Series Conformal Mappings Residue Theorem Differential Equations: Partial Differential Equations Eigenvalue problems First-Order Differential Equations Separation of Variables Series Solutions and Frobenius Methods Nonhomogeneous Differential Equations Nonhomogeneous Differential Equations Greens Theorem Greens Theorem

Instructors Assoc. Prof. Matem ERDOĞAN


Web Address

mailto:[email protected]


Course title: Spectroscopic Methods I Code: FFZ 5113 Institute: Science Field: Physics




ECTS

14x3=42 0 0 - 5x14=70 14x5=70 200 3 8


Course Type


Technical Elective

Social Elective

Course Objectives

To introduce UV-visible, FTIR and X-ray methods


1) To learn UV-visible spectroscopy 2) To learn FTIR spectroscopy 3) To learn X-ray spectroscopy


1) Organik Kimyada Spektroskopik Yöntemler, Prof. Dr. Ender Erdik, Gazi Kitabevi. 2) Enstrümantal Analiz Yöntemleri, Prof. Dr. Atilla Yıldız, Prof. Dr. Ömer Genç, Prof. Dr. Sema Bektaş, Hacettepe Üniversitesi Yayınları 3) Spectrometric Identification of Organic Compounds, R. M. Silverstein, G. C. Bassler, T. C. Morrill, John Willey& Sons Inc.

ASSESSMENT CRITERIA


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mark as (X)

Percent (%)

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Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Principles of spectroscopic methods Principles of UV-visible spectroscopy Measurement systems of UV-visible spectroscopy UV-visible spectra Analysis of UV-visible spectra Applications of UV-visible spectroscopy Principles of FTIR spectroscopy Measurement systems of FTIR spectroscopy FTIR spectra Analysis of FTIR spectra Principles of X-Ray spectroscopy Measurement systems of X-Ray spectroscopy X-Ray spectra Analysis of X-Ray spectra





Course title: Molecular Electronics I Code: FFZ 5114 Institute: Science Field: Physics




ECTS

14x3=42 0 0 - 5x14=70 14x5=70 200 3 8


Course Type

Basic Scientific

Scientific

Technical Elective

Social Elective

Course Objectives

To introduce the Molecular Electronics and its applications


1) To learn Molecular Electronics principles 2) To learn applications of Molecular electronics using organic materials 3) To learn organic-inorganic hybrid systems


Introduction to Molecular Electronics Edited by M. C. Petty, M. R. Bryce, and D. Bloor (University of Durham, U.K.). Oxford University Press: New York. 1995.

ASSESSMENT CRITERIA


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mark as (X)

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Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction of molecular electronics Theory of molecular electronics Theory of molecular electronics Organic materials in molecular electronic Applications of organic materials and its in molecular electronic Piezoelectric materials and their applications Pyroelectric materials and their applications Non-linear optics in organic materials Conduction polymers and their applications Liquid crystals and their applications Applications of carbon nanotubes in molecular electronics Biological materials in molecular electronics Nanoparticles and their applications in molecular electronics Organic-inorganic hybrid materials and their applications in molecular electronics





Course title: Modern Quantum Concepts I Code: FFZ 5115 Institute: Science Field: Physics

Education and Teaching Loads Credits Lecture Application Laboratory Project/



ECTS

14x3=42 0 0 - 5x14=70 14x5=70 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To obtain detail information regarding to quantum mechanics


1- Knowledge of the theoretical approaches used in quantum mechanics 2- An understanding of the quantum mechanics


1- Modern Fiziğin Kavramları, A. Beiser 2- Modern Quantum Mechanics (revised edition), J.J. Sakurai, Addison-Wesley 1994

ASSESSMENT CRITERIA


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Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction Interest area of quantum physics Particle characteristic of light Atom and Atom models Wave Properties of Particles Schrödinger Wave Equation Schrödinger Wave Equation One electron atoms Two electron atoms Many electron atoms Spin of electron Angular momentum and spin Angular momentum and spin Harmonic oscillator

Instructors Dr. Orhan ZEYBEK


Web Address http://www.orhanzeybek.com/



Course title: Advanced Surface Physics I Code: FFZ 5116 Institute: Science Field: Physics




ECTS

14x3=42 0 0 - 5x14=70 14x5=70 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To obtain detail information regarding to semiconductors


1- Knowledge of the theoretical and experimental approaches used in surface physics 2- An understanding of the surface physics


1- “Surface Science”, K. O URA, V.G. Lifshits, A.A. Zotov and M. Katayama, Springer 2003. 2- “Introduction to Surface Physics”, M. Prutton, Oxford Science Publications 1997.

ASSESSMENT CRITERIA


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Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction Interface, and bulk Synchrotron radiation Surface science studies with synchrotron radiation source The physics of photoemission and Inverse photoemission spectroscopy Angle-resolved photoemission spectroscopy, Auger electron spectroscopy Quasiparticle excitations Surface states of semiconductors Basic of two-dimensional crystallography Basic of two-dimensional crystallography Experimental background Experimental background Experimental background Experimental background






Course Title X-ray crystallography Code : FFZ 5121 Institute: Science Field: Physics


on Laboratory

Project/ Field Study

Homework Others Total T+A+L=Credit

ECTS

14x3=42 0 0 1x10= 10 4x15= 60 14x5=70 200 3 8

Semester Autumn Course Language Turkish/English

Course Type

Basic Scientific


Social Elective

Course Objectives

To develop strong background for the X-ray crystallography


To learn X-ray crystallography To learn the diffraction of X-rays by crystals


Fundamentals of crystallography (C. Giacovazzo) Crystals and crystal structures (Richard Tilley) Elements of Modern X-ray Physics (Jens Als-Nielsen, Des McMorrow)

ASSESSMENT CRITERIA


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mark as (X)

Percent (%)

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X 20 Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

The diffraction of X-rays by crystals “ Thomson scattering Compton scattering Interference of scattered waves Scattering by atomic electrons Scattering by atoms The temperature factor Scattering by a molecule or by a unit cell Diffraction by crystal Bragg’s law, Symmetry in reciprocal space Diffraction intensities, Anomalous dispersion The Fourier synthesis and the phase problem “

Instructors Assoc. Prof. Hülya KARA

E-Mail [email protected]

Web Address http://w3.balikesir.edu.tr/~hkara/


Course Title Magnetic properties of solids I - Code : FFZ 5122 Institute: Science Field: Physics




redit ECTS

14x3=42 0 0 1x10= 10 4x15= 60 14x5=70 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To introduce the magnetic properties of solids


To learn origins of magnetic properties of solids To learn exchange Interaction


Molecular magnetism ( Olivier Kahn) Molecular Magnetism: New Magnetic Materials (Koichi Itoh) Molecule-Based Magnetic Materials: Theory, Techniques, & Applications (Mark M Turnbull)

ASSESSMENT CRITERIA


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Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Origins of magnetic properties Larmor precession, diamagnetic susceptibility Paramagnetic susceptibility of non interacting ions, Curie's Law. Low temperature/high field behaviour - Brillouin function Comparison with experiment for rare earth ions and transition metal ions, quenching of orbital momentum, crystal fields “ Metals, Pauli susceptibility Molecular Field model, susceptibility above Curie Temperature, magnetisation below Tc. Collective Model. Exchange Interaction Magnetic energy, Bloch walls, anisotropy energy, magnetostatic energy Hard magnetic materials, BH product. Soft magnetic materials Magnetic Resonance




http://www.powells.com/s?author=Mark%20M%20Turnbull


Course title : OPTOELECTRONICS I

Code : FFZ 5123



n Laboratory Project/


redit ECTS

14x3=42 - - - 4x14= 56 14x5=70 200 3 8


Course Type

Basic Scientific


Social Electrive

Course Objectives

The purpose of this course is to learn the fundementals of the growth and fabrication techniques of modern optoelectronic devices, understand the structural, electrical and optical properties of semiconductors used in optoelectronic technologies and learn some spectroscopic techniques


1) To learn the fundemental structural, electrical and optical properties of semiconductors and their modification and be able to identify the desired properties needed for optoelectronic device technologies. 2) To learn the bulk and epitaxial growth techniques of the semiconductor materials 3) To learn the micro and nano-fabrication techniques and processes of the semicondoctor optoelectronic devices. 4) To learn the some spectroscopic techniques and be able to analyse their outputs


[1] Jasprit Singh “Semiconductor Optoelectronics , Physics and Technology” 1995, McGraw-Hill, New Jersey [2] Peter Y. Yu and Manuel Cardona, “Fundementals of Semiconductors” 2001, Springer, [3] Pallab Bhattacharya “Semiconductor Optoelectronic Devices” 1996, Prentice Hall, New Jersey

ASSESSMENT CRITERIA


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Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction: The information age and its demands Semiconductors: Crystal structures, expitaxial growth and micro-nano fabrications Optical properties of semiconductors Macroscopic electrodynamics Dielectric functions Excitons and Exciton-Polaritons Phonon-Polaritons and lattice absorption Modulation spectroscopy Emission spectroscopy Emission spectroscopy Light scattering spectroscopy Light scattering spectroscopy Photoelectron spectroscopy Photoelectron spectroscopy





Course title: Technology of Vacuum I Code: FFZ 5125 Institute: Science Field: Physics




ECTS

14x3=42 0 0 - 5x14= 70 14x5=70 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To obtain detail information regarding to technology of vacuum


1- Knowledge of the theoretical and experimental approaches used in technology of vacuum 2- An understanding of the technology of vacuum


1- “Modern Vacuum Practise”, N. Harris, Mc Graw Hill. 2- “Basic Vacuum Practice”, Varian Vacuum Products Division.

ASSESSMENT CRITERIA


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mark as (X)

Percent (%)

If any,

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Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction Vacuum fundamentals Vacuum fundamentals Vacuum fundamentals Some relevant physical concepts Some relevant physical concepts Some relevant physical concepts Vacuum measurement Vacuum measurement Vacuum pumps Vacuum pumps Vacuum pumps Gauges Gauges






Course Title: Properties of Ferromagnetic Materials

Code : FFZ 5126 Institute: Science Field: Physics




ECTS

14x3=42 5x14= 70 14x5=70 200 3 8


Course Type


Technical Elective

Social Elective

Course Objectives

Investigation of the magnetic and physical properties of ferromagnetic materials


1. Apply knowledge of natural sciences (Mathematics, Physics, Chemistry). 2. Justify and analyze natural phenomena. 3. Identify, formulate, and solve field related problems. 4. Interdisciplinary knowledge association and application. 5. Direct correlation and application of gained knowledge with technology and industry. 6. Get an understanding of professional and ethical responsibility. 7. Get a recognition of the need for, and an ability to engage in life-long learning.

8. Gain a knowledge of contemporary issues.


1. Mustafa Göktepe, “Encyclopdia of Sensors : Magnetic Stress Sensors”, American Scientific Publishers, USA, Vol.5, 2006, pp. 415-466.

2. Pavel Ripka, “Magnetic Sensors and Magnetometers”, Artech House, UK, 2000, pp. 494. 3. Jakob Fraden, “Handbook of Modern Sensors”, Springer, USA, 2003, pp. 589. 4. David Jiles, “Magnetism and Magnetic Materials” Chapman & Hall, USA, 1989, pp. 440. 5. Robert C. O’Handley, “Modern Magnetic Materials, Principles and Application”, John-

Willey&Sons, USA, 2000, pp 740. 6. Richard M. Bozorth “Ferromagnetism”, IEEE Press, USA, 1993, pp. 968. 7. Alex Hubert, Rudolf Schafer, “Magnetic Domains” , Springer, Germany, 1998, pp. 696.

8. B.D. Cullity, “Introduction to Magnetic Materials”, Adisson-Wesley Pub.Co., 1972, pp. 666.

ASSESSMENT CRITERIA


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Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction to ferromagnetic materials Magnetic properties of the ferromagnetic materials Magnetization of the ferromagnetic materials Magnetic domains Influence of stress on magnetic domains Investigation of energy in magnetic domains Investigation of the magnetic domain observation techniques Investigation of magnetic properties in ferromagnetic crystals Investigation of magnetic properties in amorphous ferromagnetic materials Influences on magnetization in ferromagnetic materials Ferromagnetic materials for use on magnetic sensor and transducer application Magnetic sensors Influences of the heat treatment on magnetic properties of ferromagnetic materials Magnetic transducers and transformers

Instructors Assoc. Prof. Dr. Mustafa GÖKTEPE


Website w3.balikesir.edu.tr/goktepe


Course Title: Magnetic Sensors Code : FFZ 5127 Institute: Science Field: Physics



Credit ECTS

14x3=42 5x14= 70 14x5=70 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

Understanding of the operating principles of magnetic sensors


1. Apply knowledge of natural sciences (Mathematics, Physics, Chemistry). 2. Justify and analyze natural phenomena. 3. Identify, formulate, and solve field related problems. 4. Interdisciplinary knowledge association and application. 5. Direct correlation and application of gained knowledge with technology and industry. 6. Get an understanding of professional and ethical responsibility. 7. Get a recognition of the need for, and an ability to engage in life-long learning. 8. Gain a knowledge of contemporary issues.


1. R. Boll, K.J. Overshot, “Magnetic Sensors”, VCH, UK, 1989, pp. 513. 2. Mustafa Göktepe, “Encyclopdia of Sensors : Magnetic Stress Sensors”, American Scientific

Publishers, USA, Vol.5, 2006, pp. 415-466. 3. Pavel Ripka, “Magnetic Sensors and Magnetometers”, Artech House, UK, 2000, pp. 494. 4. Jakob Fraden, “Handbook of Modern Sensors”, Springer, USA, 2003, pp. 589. 5. David Jiles, “Magnetism and Magnetic Materials” Chapman & Hall, USA, 1989, pp. 440. 6. Robert C. O’Handley, “Modern Magnetic Materials, Principles and Application”, John-

Willey&Sons, USA, 2000, pp 740. 7. Richard M. Bozorth “Ferromagnetism”, IEEE Press, USA, 1993, pp. 968. 8. Alex Hubert, Rudolf Schafer, “Magnetic Domains” , Springer, Germany, 1998, pp. 696. 9. B.D. Cullity, “Introduction to Magnetic Materials”, Adisson-Wesley Pub.Co., 1972, pp.

ASSESSMENT CRITERIA


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mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction to sensors Magnetic sensors The operating principles of magnetic sensors Magnetic domains Investigation of the magnetic domains in sensor cores Influence of stress on magnetic domains Force measurements Mass measurements Torque measurements Displacement measurements Temperature measurements Ferromagnetic materials and their use on sensor applications Influences of the heat treatment on magnetic properties of ferromagnetic materials Magnetic transducers and transformers





Course title: Surface Science Techniques I Code: FFZ 5128 Institute: Science Field: Physics




ECTS

14x3=42 0 0 - 5x14=70 14x5=70 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To learn surface science techniques


1- Knowledge of the experimental techniques used in materials characterization. 2- An understanding of the most common surface science techniques


1- “Handbook of Surface and Interface Analysis”, Edited by: J.C. Rivière and S. Myhra, Publisher: Marcel Dekker Inc. 2- “Methods of Surface Analysis”, Edited by: J.M. Walls, Cambridge University Press

ASSESSMENT CRITERIA


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mark as (X)

Percent (%)

If any,

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Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction to Surface science techniques Elements of problem-solving Photoemission spectroscopy Photoemission spectroscopy Inverse photoemission spectroscopy Ultraviolet photoelectron spectroscopy X-ray photoelectron spectroscopy X-ray diffraction spectroscopy Auger electron spectroscopy Ion scattering spectroscopy Introduction to scanned probe microscopy Scanning tunneling microscopy Scanning tunneling microscopy Atomic force microscopy






Course title: Surface Physics of Semiconductor I





ECTS

14x3=42 0 0 - 5x14=70 14x5=70 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives



1- Knowledge of the experimental techniques used in semiconductors. 2- An understanding of the semiconductors.


1- Kittel C., “Introduction to Solid State Physics”, Türkçesi Karaoğlu B., Güven Yayıncılık, İstanbul, 1996.

2- Morgan D. V., Moses A. J., “III-V Quantum System Research”, Peter Peregrinus Ltd, London, 1995

3- Biasiol G. , Sorba L.,“Molecular Beam Epitaxy: Principles and Applications”, Eds, Edizioni ETS, Pisa, 2001 4- Singleton J., “Bant Theory and Electronic Properties of Solids”, Oxford University Press, Great Britain, 2003. 5- Wilson J., Hawkes J. F. B., “Optoelectronics”, Türkçesi Okur İ., Değişim Yayınları, Adapazarı, 2000

ASSESSMENT CRITERIA


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mark as (X)

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If any,

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Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Basic concepts of semiconductors Crystal structures Preparation of clean surfaces Interaction of surfaces with gases Surface processing techniques Introduction of crystal growth, conditions of ultrahigh vacuum Molecular beam epitaxy Molecular beam epitaxy Molecular beam epitaxy Growth processing in ultrahigh vacuum Characterization methods (RHEED, Elipsometer, reflactance) Characterization methods (RHEED, Elipsometer, reflactance) Characterization methods after growth (Auger electron spectroscopy, XRD, photoluminescence) Characterization methods after growth (Auger electron spectroscopy, XRD, photoluminescence)

Instructors Assis. Prof. Dr. Orhan ZEYBEK





Course title: MAGNETISM AND MAGNETIC MATERIALS

Code: FFZ 5133





ECTS

14x3=42 0 0 - 5x14=70 14x5=70 200 3 8


Course Type Basic Scientific Scientific

Technical Elective

Social Electrive

Course Objectives

The description and existence of magnetisation in magnetic materials


Magnetic fields Magnetisation and magnetic moment Magnetic measurements Magnetic materials Magnetic properties Magnetic domains Domain walls Domain processes Magnetic order and critical phenomena Magnetic order and critical phenomena Electronic magnetic moments Quantum theory of magnetism Magnetic recording


[1] D. Jiles, “Introduction to Magnetism and Magnetic Materials”, Chapman & Hall, London. [2] R. M. Bozorth “Ferromagnetism”, D: Van Nostrand Company Inc. Princeton. [3] Translations editors: Prof. Dr. Kemal Çolakoğlu; Editörler: R.A. Serway, R.C. Beichner, J.W. Jevett, “Physics for Scientists and Engineers ”, Palme, Ankara. [4] D.J. Maps, “Applications in Magnetic Recording”, School of Electronic, Communication and Electrical Engineering, University of Plymouth. [5] D. Craik, “Magnetism Principles and Applications”, Universtiy of Nottingham. [6] C. Kittel, “Introduction to Solid State Physics” 6th edition translation by B. Karaoğlu, Güven Ltd. Şti.

ASSESSMENT CRITERIA


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mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Magnetic fields Magnetisation and magnetic moment Magnetic measurements Magnetic materials Magnetic properties Magnetic domains Domain walls Domain processes Magnetic order and critical phenomena Magnetic order and critical phenomena Electronic magnetic moments Electronic magnetic moments Quantum theory of magnetism Magnetic recording

Instructors Prof.Dr. Hakan KÖÇKAR


Web Address


Course Title: Statistical Mechanics

Code : FFZ 5135






ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Fundamental Field Course

Field Course

Technical Optional

Social Optional

Course Objectives

To learn the basic concepts of numerical calculation at physics upgrade’s degree


To learn the thermodynamic Laws and Basic Statistical Relations , To learn the Statistical Approach, To learn the Micro canonical Ensemble, To learn the computation of the numerical derivation and the integrals, To compute the Quantum Statistics of Ideal Gases, To learn the , Fermi-Dirac Statistics, To learn the Bose-Einstein Statistics,


[1] Bekir KARAOĞLU, İstatistik Mekaniğe Giriş, Seyir Yayıncılık, 2003, İstanbul. [2] Frederick Reif, Fundamentals of Statistical and Thermal Physics, McHill,1965.

ASSESSMENT CRITERIA


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Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Thermodynamic Laws and Basic Statistical Relations Statistical Approach “ Micro canonical Ensemble “ Canonical Ensemble “ Quantum Statistics of Ideal Gases “ Fermi-Dirac Statistics “ “ Bose-Einstein Statistics “

Instructors Assist. Prof. Dr. Mehmet BAYIRLI


Web Address



Course Title: Physics of Semiconductors and

Their Heterostructures –I Code : FFZ 5136

Institute: Science

Field: Physics

Education and Teaching Methods Credits Lecture Application Lab. Project/


Other Total

Credit T+A+L=Credit

ECTS

14x3= 42 0 0 - 5x14= 70 14x5=70 200 3 8

Semester Autumn Language Turkish

Course Type

Basic Scientific


Social Elective

Course Objectives

The defini tion of heterostructures and semiconductors

Learning Outcomes and Competencies

To have an background for semiconductor heterostructures and semiconductors

Textbooks and /or References

All books of semiconductors and lecture notes

ASSESSMENT CRITERIA


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mark as (X) Percent

(%)

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Homework x 25 Term Paper

Term Paper, Project Reports, etc.

Oral Examination


Final Exam x 75 Other

Other

Week Subjects

1 Properties of Crystals, Atom bindings 2 Band Models 3 The free electron picture, crystal structures, 4 Wave diffraction in periodic structure, Electrons in periodic structures 5 Carrier concentrations in semiconductors: 6 Conduction in semiconductors 7 Semiconductor band structure 8 Band structure modifications alloys and heterostructures, band structure

modifications through strain 9 İstatistics, Effective Mass 10 Doping of semiconductors 11 Intrinsic semiconductors, extrinsic semiconductors 12 Lattice vibrations phonons, Transport:General formalism. 13 Defects and carrier-carrier scatterings

14 Phonon scattering Instructors Assoc. Prof. Dr. Sibel Gökden


Website w3.balikesir.edu.tr/sozalp



Course Title: CALCULATION AND SIMULATION I

Code : FFZ5138


Education and Teaching Methods Credits

Lecture Application

Laboratuary Project/ Field Study

Homework


ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives



To learn the problem of the analytic and numerical, To learn the operation of matrices, To learn the calculation of the linear and non-linear equations, To learn the computation of the numerical derivation and the integrals, To compute the Fourier series, To learn the basic concepts of numerical calculations, To learn the calculation of the differential equations, To learn the operation of matrix, numerical derivation, numerical integrals and Fourier series,


[1] Tapmaz, Recep, Sayısal Çözümle, Literatür Yayıncılık, 2002, İstanbul. [2] Karagöz, İhsan, Sayısal Analiz ve Mühendislik Uygulamaları, UÜ Güçlendirme vakfı Yayını,2001,Bursa. [3] I. S. Skolnikoff, R. M. Redheffer, Mathematics of Physics and Modern Engineering, 1966.

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Numerical equations solutions Numerical polinom roots solutions Linear equations Matrix operations I Matrix operations II Linear equations fits Non-linear equations fits Numerical derivations and solutions I Numerical integral I Numerical integral II Fourier series and transports Differential equations solutions I Differential equations solutions II Data operations



Web Address



Course title: Advanced Condensed Matter Physics I





ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To obtain detail information regarding to condensed matter physics.


1- Knowledge of the theoretical and experimental approaches used in condensed matter physics 2- An understanding of the condensed matter physics


1- “Introduction to Solid State Physics”, C. Kittel, Seventh Edition, John Wiley and Sons Inc. 1996. 2- “Katıhal fiziğine giriş”, M. Dikici, Ondokuz Mayıs Üniversitesi, Samsun, 1993.

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Crystal structures Crystal structures Crystal structures Crystal structures Reciprocal lattice Reciprocal lattice Crystal binding Crystal binding X-ray, neutron and electron diffraction in crystals X-ray, neutron and electron diffraction in crystals X-ray, neutron and electron diffraction in crystals Lattice vibrations Lattice vibrations Lattice vibrations






Course title: MAGNETIC NANOSTRUCTURES

Code: FFZ 5144





ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Compulsory

Compulsory

Technical Elective

Social Electrive

Course Objectives

Characterisation and Fabrication of Nanomagnetic Materials


Nanostructures Fabrication of the ordered magnetic nanostructures Magnetic properties Structural properties Interactions between magnetic arrays and other systems



ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction Nanostructures Nanostructures Fabrication of the ordered magnetic nanostructures Fabrication of the ordered magnetic nanostructures Fabrication of the ordered magnetic nanostructures Magnetic properties Magnetic properties Magnetic properties Structural properties Structural properties Interactions between magnetic arrays and other systems Interactions between magnetic arrays and other systems Interactions between magnetic arrays and other systems



Web Address


Course Title: CHARGED PARTICLE PHYSICS


Education and Teaching Methods Credits Lecture Applicati. Laborator

y Project/Field Study

Homework Other Total T+A+L=Credit

ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific Scientific Technical Optional

Social Optional

Course Objectives

To learn the interactions between charged particles and matter with detailed


To learn nuclear reactions, To learn the charged particle interactions


The Atomic Nucleus R.D. EVANS Mc-Graw-Hill, 1955. Nuclear Physics I. KAPLAN Addison-Wesley Company, 1962. Nuclear Physics W.E. BURCHAM Logman G. U. ,1973.

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Conservations Laws for Nuclear Reactions “ “ Energy Dependence of Nuclear Reaction Cross Sections “ “ Ionization of Matter by Charged Particles “ “ Elastic Scattering of Electrons and Positrons “ “ Radiative Collisions of Electrons with Atomic Nuclei “ “ Stopping of Electrons by Thick Absorbers “ “ Passage of Heavy Charged Particles through Matter “ “

Instructors Prof. Dr. ASUMAN AYDIN


Web Address w3.balikesir.edu.tr/aydina


Course Title: Quantum Field Theory-I

Code : FFZ5149



Field Study

Homework


ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type


Technical Elective

Social Elective

Course Objectives

- Introducing students to advanced topics of QFT.


The student must be able to : - calculate basic Feynman Diagrams.


An Introduction to Quantum Field Theory Michael E. Peskin & Daniel V. Schroder Addison-Wesley ISBN 0-201-50397-2

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction to 4-vectors Klein Gordon Field Klein Gordon Field Dirac Field Dirac Field - Dirac Matrices Discrete Symmetries Interacting Fields and Feynman Diagrams Interacting Fields and Feynman Diagrams Interacting Fields and Feynman Diagrams Interacting Fields and Feynman Diagrams Basic Processes of Quantum Electrodynamics Basic Processes of Quantum Electrodynamics -Cross Sections Quantum Electrodynamics-Crossing Symmetries Quantum Electrodynamics-Basic Processes

Instructors Doç. Dr. Levent SOLMAZ


Website w3.balikesir.edu.tr/lsolmaz


Course Title: Introduction to Cosmology Code : FFZ 5150


Education and Teaching Methods Credits Lecture Application Laboratu

ary Project/



ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type


Technical Elective

Social Elective

Course Objectives

- Introducing students to basic concepts of cosmology


The student must be able to :

describe the main events of the universe


Liddle, A., An Introduction to Modern Cosmology 2nd ed. (Wiley), Rowan-Robinson, M., Cosmology, 3rd ed. (Oxford) , Harrison, E., Cosmology: the Science of the Universe, 2nd ed (CUP) , Peacock, J.A., Cosmological Physics, (CUP)

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

The realm of the galaxies The realm of the galaxies Dynamics of the Universe Dynamics of the Universe- curved space Measuring the Universe Measuring the Universe- accelerating universe The Big Bang- overview The Big Bang-thermal history The Big Bang- nucleosynthesis The Big Bang- recombination The Cosmic Microwave Background The Cosmic Microwave Background; phenomenology; The Cosmic Microwave Background; theory of fluctuations; Implications for geometry

Instructors Doç. Dr. Levent SOLMAZ




Course title : ORGANIC THIN FILM FABRICATION TECHNIQUES

Code : FFZ 5151




redit ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type Basic Scientific


Social Electrive

Course Objectives

To obtain knowledge on organic Thin Film Fabrication Techniques


To investigate the organic materials and compare them with the inorganic ones.

To obtain information on the organic Thin Film Fabrication Techniques


Books on the Thin Film Fabrication Techniques

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)








Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction Organic materials Chemical Thin Film Deposition Self Assembly Thin Film Deposition Technique Self Assembly Thin Film Deposition Technique Spin Coating Thin Film Deposition Technique Spin Coating Thin Film Deposition Technique LB Thin Film Deposition Technique LB Thin Film Deposition Technique LB Thin Film Deposition Technique LB Thin Film Deposition Technique Other Techniques Other Techniques Other Techniques

Instructors Asist. Prof. Dr. İnci ÇAPAN

E-mail [email protected], [email protected]

Web Address w3.balikesir.edu.tr/ibasaran



Course title : ORGANIC GAS SENSORS Code : FFZ 5152 Institute: Science Field: Physics



redit ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Electrive

Course Objectives

To obtain knowledge on organic gas sensors


Learning the working principles of gas sensors and the advantages of using organic materials in gas sensing applications


Organic gas sensor books

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)








Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction Inorganic gas sensors Inorganic gas sensors The gas sensor types in use The fundamental working prinsibles of gas sensors The fundamental working prinsibles of gas sensors Properties of an ideal gas sensor Advantages of organic gas sensors Chemical based gas sensors Physical based gas sensors The ways to increase the performance of a gas sensor Polymer based gas sensors Porphyrin based gas sensors Phythalocyanine based gas sensors






Course Title Fundamentals of Crystallography Code : FFZ 5153 Institute: Science Field: Physics


on Laboratory



ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To form background for crystallography


To learn Crystal structures and Crystals systems To learn Symmetry in crystals, point group, space group



ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)








Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Crystals and Crystals structures “ Symmetry in crystals Crystals systems Lattices Crystallographic planes, and directions Two dimensional patterns and tiling Symmetry in three dimensions “ Point group and symmetry classes “ The space groups “ “





Course Title: Many Particle Theory I Code : FFZ 5156 Institute: Science Field: Physics



Credit ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Compulsory Area Technical Elective

Social Elective

Course Objectives

The aim of the course is to introduce principles of many particle physics in the graduate level.


The student will gain the necessary tools to pursue his/her own research in condensed matter physics.


Many-Body Theory of Solids, J.C. Inkson, Plenum Press, 1984. Many-Particle Physics, G.D. Mahan, Plenum Press, 1990.

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)



Homework X 20 Term Paper



Laboratory Work -- -- Final Exam


Other -- --

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Green's function of the single particle Schrodinger equation Second quantization Representations of quantum mechanics Interacting systems and Quasiparticles Zero-temperature many-body Green's functions The self-energy and perturbation series The screened interaction and selective summations Diagrammatic interpretation of the Green's function series Green's functions at finite temperatures Spectral function; Thermodynamic potential; Frequency summations Linear response theory Kubo formula for electrical conductivity Electron gas Model dielectric functions

Instructor/s Assoc.Prof.Dr.Ersen Mete


Website http://w3.balikesir.edu.tr/~emete


Course Title: Magnetic Resonance I

Code : FFZ 5157





ECTS

14x3=42 0 0 - 5x14=70

88 200 3 8


Course Type


Technical Elective

Social Elective

Course Objectives

Learning of principal concept of magnetic resonance, learning the NMR technique, to have capability collecting the useful information from the spectrum


1) To learn basic concepts of Magnetic resonance 2) to have the capability of investigation of spin system 3) to write the motion equations of spin systems 4) to determine the energy absorbed by spin system 5) to learn the experimental technique in Magnetic Resonance 6) To understand the NMR in solid and liquid 7) to learn the condition that effect the spectrum 8) to have capability collect NMR spectrum


1. Apaydın, F. 1996, Magnetik Rezonans, H.Ü. Mühendislik Fakültesi Ders Kitapları, Ankara. 2. Poole, C.P. and Farach, H.A., 1972, The Theory of Magnetic Resonance, John Wiley, New

York

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Spectroscopy and Magnetic Resonance Basic principal of Magnetic Resonance Magnetic Moment Dynamic investigation of Spin System; Classical Method Motion equations in Isolated spin system Motion equations in unisolated spin system The energy absorbed by Spin System Experimental Methods in Magnetic Resonance I: NMR Continues wave NMR Pulse spectrometers Measurement of relaxation times NMR in solids Dipol-Dipol interactions NMR in liquids

Instructors Asist. Prof. Hasan TUNER


Website w3.balikesir.edu.tr/htuner


Course title : QUANTUM ELECTRONICS I Code : FFZ 5158





ECTS

14x3=42 - - - 4x15= 60

98 200 3 8


Course Type

Basic Scientific


Social Electrive

Course Objectives

To learn the main principles of quantum mechanics and electromagnetism their applications in optical system


Gaussian beam propagation in lenslike media, optical resonator, density matrix formulation of the interaction of light and matter


[1] Ammon Yariv “ Quantum Electronics” 1989, John Wiley & Sons Inc

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Basic theorems and postulates of quantum mechanics Some solutions of the Time-Independent Schrodinger equation Matrix formulation of quantum mechanics Matrix formulation of quantum mechanics Lattice vibrations and their quantization Lattice vibrations and their quantization Electromagnetic field and their quantization Electromagnetic field and their quantization Propagation of optical beams in homogeneous and lens -like media Propagation of optical beams in homogeneous and lens-like media Optical resonators Optical resonators Interaction of radiation and atomic systems Interaction of radiation and atomic systems





Course title: THIN FILM TECHNOLOGY Code: FFZ 5159





ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Electrive

Course Objectives

Production of thin films by using different physical and chemical techniques


Vacuum technology Physical methods of film deposition Evaporated films Sputtered films Chemical methods of film deposition Electrodeposited films Physical-chemical methods of film deposition Substrates Techniques and facilities for large scale manufacture


H. Kockar, Materials lecturer handouts, 2001.

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction Vacuum technology Physical methods of film deposition Evaporated films Evaporated films Sputtered films Sputtered films Chemical methods of film deposition Electrodeposited films Electrodeposited films Physical-chemical methods of film deposition Physical-chemical methods of film deposition Substrates Techniques and facilities for large scale manufacture



Web Address


Course Title: Introduction to Computational Condensed Matter Physics I

Code : FFZ5160

Institute: Natural and Applied Sciences Field: Physics


Field Study Homework Other Total Credit

T+A+L=Credit ECTS

16x3=48

Duration of lectures (16x3 total

of 48 lecture hours)

0 0 0 5x15=75

16x5=80 Out of class self-study (preperation, exercises)

2x15= 30 (Midterm)

1x20= 20 (Final exam)

253 3 8

Semester Fall Language Turkish/English


Technical Elective

Social Elective

Course Objectives

The aim of the course is to introduce computational methods in condensed matter physics at the graduate level.


The student will gain the necessary tools to pursue his/her own research in computational condensed matter physics, in particular in the field of electronic structure calculations. Students should be able to derıve Kohn-

Sham equations.


Electronic Structure, Richard M. Martin, Cambridge University Press, 2004.

Atomic and Electronic Structure of Solids, Efthimios Kaxiras, Cambridge University Press, 2003.

Electronic Structure Calculations for Solids and Molecules, Jorge Kohanoff, Cambridge Univ. Press, 2006.

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1

2

3 4

5

6

7

8 9

10

11

12

13 14

System of interacting electrons and nuclei

Thomas-Fermi model

Crystal structures, reciprocal lattice Energy band theory of solids

Tight-Binding model

Variational principle and Hartree model

Hartree-Fock theory

Koopman's theorem and Roothaan's expansion Hellmann-Feynman theorem and functional derivatives

Total energy in terms of electron density

Hohenberg-Kohn Theorems

N- and V-representability, fractional total particle number

Kohn-Sham equations Fractional occupations and Janak's theorem





Course Title: An introduction to stellar

astrophysics

Code : FFZ5161

Institute: THE INSTITUTE OF SCIENCE

AND TECHNOLOGY

Field: PHYS ICS



T+A+L=Credit ECTS

3 3 3 8


Course Type

Basic Scientific


x Social Elective

Course Objectives

To obtain knowledge on stellar propert ies


Learn ing the properties of stars


Books on stellar astrophyscis

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)



Homework Term Paper


x 40 Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction

Locations of stars Locations of stars

Magnitudes of stars

Magnitudes of stars

The colour-magnitude diagrams

The colour-magnitude diagrams The colour-magnitude diagrams

Stellar Luminosities

Stellar Luminosities

The effective temperatures of stars

The effective temperatures of stars Masses and radii of stras

Masses and radii of stras

Instructor/s Asist. Prof. Dr. Gülay İNLEK


Website


Course Title: Nonlinear Physics I Code : FFZ5162 Name of The program: PHYSICS

Education and Teaching Loads Credits

Theory Application Laboratory Project/Field Study

Homework Other Total Credit ECTS Credit

16x3= 48

0

0

-

5x15=75

16x5=80 1x15= 15 Midterm

exam 1x20= 20 Final exam

238

5

8

Semester Fall Course Language Turkish

Kind of Course Fundamental

Field Course Field

Course Technical Optional Social Optional

Content of

Course

Introduction None-Linear physics, chaos, solitons, complex systems, fractals and mathematical computations

for none linear physics

Purpose Of the

Course To learn the basic concepts of numerical calculation at physics upgrade’s degree

Learning

Output(s) and Efficiencies

To learn the content of none linear physics,

To learn the chaos,

To learn the none equilibrium, To learn the basic concepts of numerical calculations,

To learn the calculation of the differential equations in none linear physics.

Course Book

and/or other Sources

[1] Tapmaz, Recep, Sayısal Çözümle, Literatür Yayıncılık, 2002, İstanbul.

[2] Karagöz, İhsan, Sayısal Analiz ve Mühendislik Uygulamaları, UÜ Güçlendirme vakfı

Yayını,2001,Bursa.

[3] Lui Lam, Non-Linear physics for beginners, Word Scientific, 1998.

EVALUATION CRITERION

Theoretic Course Project Course

to mark (X) Percentage

(%) to mark(X) Percentage (%)

Midterm Exam

X 30

Midterm Exam

Quiz X 5

Homeworks X 5

Semester homework

(Project,report ) Oral Exam

Laboratory Final Exam


Other

Week Course Subjects

1

2

3

4 5

6

7

8

9 10

11

12

13

14

Introduction None-Linear physics

Computation the scaling parameters

Computation the box dimension

Differential equations solutions I Differential equations solutions II

Differential equations solutions III

Differential equations solutions IV

Nonlinear systems

Chaos Solitons

Complex systems

Quantum chaos

Interacting maps

Fractals

Course Teacher Yrd. Doç. Dr. Mehmet BAYIRLI


Web Address



Course Title: Particle Physics I

Code : FFZ5164

Institute: Institute of Science Field: Physics



T+A+L=Credit ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8

Semester Autumn Language English

Course Type


Technical Elective

Social Elective

Course Objectives

To provide a framework for understanding the Particle Physics I.


To gain the goals and contents given below: Introduction to Elementary Particles, Classification of Elementary Particles, Elementary Particle Dynamics, Relativistic Kinematics, Symmetries, Bound States, The Feynman Calculus, Scattering Process, Cross Section, Decay Widths and Branching Ratio, Lifetimes


Introduction to Elementary Particles, David Griffiths, John Wiley & Sons, Inc.ISBN 0-471-60386-4

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction to Elementary Particles Classification of Elementary Particles Elementary Particle Dynamics, Elementary Particle Dynamics, QED, QCD, Weak Interactions Relativistic Kinematics Lorentz Transformations, Four-Vectors Energy and Momentum Symmetries, Groups and Conservation Laws Flavor Symmetries, Parity, Charge Conjugation, CP Violation Bound States The Feynman Rules Scattering Process, Cross Section Decay Widths and Branching Ratio Lifetimes

Instructor/s Prof.Dr.Levent SOLMAZ


Website

GRADUATE CURRICULUM DETAILS

Course Title: Material Production And Characterization Techniques-I Code : FFZ5166



Lecture Application Laboratory Project/ Field Study

Hw. Others Total Credit ECTS Credit

14x3= 42 0 0 - 14x6= 84 14x6=84 210 3 8

Semester Autumn/Spring Course Language Turkish

Course Type


Technical Elective

Social Elective

Course Objectives

To introduce special experimental methods and techniques about material production and characterization to greduate students who need to work experimentally.


1) To learn basic concepts of material physics 2) To learn classification and application area of materials 3) To learn material designing and material production techniques 4) To learn obtaining single crystals and experimental techniques of crystal growth 5) To understand spectroscopic methods which using for investigation of materials


Introduction to Solid State Physics (C. Kittel) Modern Fiziğin Kavramlar ı (Arthur Beiser, Çev.: Gülsen Önengüt, Akademi yayıncılık, Ankara)

Fundamentals of crystallography (C. Giacovazzo) Enstrümantal Analiz Yöntemleri (Prof.Dr. Atilla Yıldız, Prof.Dr. Ömer Genç, Prof.Dr. Sema Bektaş, Hacettepe Yayınları) Nanophysics and Nanotechnology (Edw ard L. Wolf, Wiley-VCH)

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)


Quizzes 5 Midterm Controls



X Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction to material physics, basic concepts of material physics ” ” ” ” ” ” ” Classification of materials, Crystalline and amorphous materials,

Industrial materials (metal, ceramic, plastic, composite materials) Application area of materials

Material design and techniques of material production ” ” ” ” ”

Synthesis of single-crystal

Crystal Growth Techniques, single crystal experimental techniques ” ” ” ” ” ” ” Spectroscopic methods for analysis of materials; Electron microscopy, Scanning Electron

Microscopy, Scanning Tunneling Electron Microscopy, Atomic Force Microscopy ” ” ” ” ” ” ” Applied Research Laboratory Study

Instructors Assist. Prof. Yasemin ACAR


Web Address http://w3.balikesir.edu.tr/~yahsi/


Course Title: MAGNETO-STRUCTURAL CORRELATIONS OF CRYSTALS Code : FFZ5167





14x3= 42 0 0 - 14x6= 84 14x6=84 210 3 8


Course Type


Technical Elective

Social Elective

Course Objectives

To introduce the correlation of crystal structure and magnetic properties.


1) To learn basic concepts of crystal physics and magnetism 2) To understand single crystal structures 3) To learn structural analysis methods for single crystals. 4) To learn experimental techniques for investigating magnetic properties of single crystals. 5) To understand magnetic exchange interactions in crystals. 6) To understand the correlation of crystal structure and magnetic properties


Fundamentals of crystallography (C. Giacovazzo) Crystals and crystal structures (Richard Tilley) Molecular magnetism ( Olivier Kahn) Molecule-Based Magnetic Materials: Theory, Techniques, & Applications (Mark M Turnbull)

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





X Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Basic concepts of crystal physics

Crystal symmetry, point groups, space groups Structural analysis methods of single crystals, X-ray diffraction method ” ” ” ” ” ” ” ” Crystal structure solving and refining Basic concepts of magnetism, Magnetic exchange interactions, Super exchange interaction Magnetic susceptibility equations of transition metal complexes ” ” ” ” ” ” Experimental methods for investigation of magnetic properties of single crystals SQUID (Superconducting QUantum Interference Device) method Magnetic properties of transition metal complexes Magneto structural correlations of crystals ” ” ” ” Computerized application






Course Title: Alloys, Superlattices and Nanostructured Magnetic Materials

Code : FFZ5168

Institute:Science Field: Physics



T+A+L=Credit

ECTS

14x3=42 0 0 - 5x14= 70

14x5=70 Exterior study hours (preliminary, review) 1x8=8 (Midterm) 1x10= 10 (Final examination

200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To obtain detailed information about characteristics and fabrication of alloys, superlattices and nanostructured magnetic materials.


Learning the characteristics and fabrication of alloys, superlattices and nanostructured magnetic materials


M. Schlesinger, M. Pouvonic "Modern Electroplating " (Fourth edition), John Willey & Sons, Newyork 2000. A.Brenner, " Electrodeposition of Alloys Principles and Practic e ", Academic Press. L.Robert White, " Giant Magnetoresistance:A premier "IEE Trans.Mag. (1992),28, 2482. e.Y.Tsymbal, D.G.Pettifor, "Perspectives of giant Magnetoresistance "Solid State Physics, Edited by H.Ehrenreich,F.Spaepen, Academic Press 56, (2001). D.J. Maps, “Applications in Magnetic Recording”, School of Electronic, Communication and Electrical Engineering, University of Plymouth.

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction Alloys Nanostructured Magnetic Materials Multilayers Superlattices Fabrication techniques of the nanostructured magnetic materials Fundamentals of electrodeposition Parameteres affecting electrodeposition Parameteres affecting electrodeposition Electrodeposition of alloys Electrodeposition of Superlattices Magnetoresistance Giant Magnetoresistance Technological applications of nanostructured magnetic materials

Instructor/s Asist. Prof. Dr. Hilal KURU


Website


Course Title: Radiation Dosimetry I

Code : FFZ5169

Name of the Programme: Physics


Lecture Application Laboratuary Project/

Field Study

Hw. Other Total Credit ECTS

16x3= 48 0 0 - 5x15=

75

16x5=80

(preliminary work)

1x15= 15 (Midterm)

1x20= 20 (Final)

238 3 8

Semester Autumn/Spring Language Turkish/English

Course Type

Basic Scientific


Social Elective

Course Contents

Basic principals of Magnetic Resonance, Magnetic Moment, Dynamic investigation of spin systems; Motion

equations in isolated spin systems, The energy absorbed by spin system, Experimental techniques in magnetic

resonance, Pulse spectrometers, Measurement techniques of relaxation times, NMR in solids, Dipol-Dipol

interaction, NMR in liquid

Course Objectives

Learning of principal concept of magnetic resonance, learning the NMR technique, to have capability collecting the

useful information from the spectrum


1) To learn basic concepts of Magnetic resonance

2) to have the capability of investigation of spin system

3) to write the motion equations of spin systems

4) to determine the energy absorbed by spin system

5) to learn the experimental technique in Magnetic Resonance

6) To understand the NMR in solid and liquid

7) to learn the condition that effect the spectrum

8) to have capability collect NMR spectrum


1. Apaydın, F. 1996, Magnetik Rezonans, H.Ü. Mühendislik Fakültesi Ders Kitapları, Ankara.

2. Poole, C.P. and Farach, H.A., 1972, The Theory of Magnetic Resonance, John Wiley, New York

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Spectroscopy and Magnetic Resonance

Basic principal of Magnetic Resonance

Magnetic Moment

Dynamic investigation of Spin System; Classical Method Motion equations in Isolated spin system

Motion equations in unisolated spin system

The energy absorbed by Spin System

Experimental Methods in Magnetic Resonance I: NMR

Continues wave NMR Pulse spectrometers

Measurement of relaxation times

NMR in solids

Dipol-Dipol interactions

NMR in liquids





Course Title: Electron Spin Resonance Spectroscopy I

Code : FFZ5170




Field Study


16x3= 48 0 0 - 5x15=

75

16x5=80

(preliminary work)

1x15= 15 (Midterm)

1x20= 20 (Final)

238 3 8


Course Type

Basic Scientific


Social Elective

Course Contents

Basic principals of Electron Spin Resonance, Spin hamiltonien, Terms of Spin Hamiltonien, Spectrum shape,

ESR in liquids, ESR in single crystals, Relaxation times, linewidths and kinetic phenomena

Course Objectives

To understand the Electron Spin Resonance technique and theory


1) To learn basic concepts of Electron spin resonance

2) 4) to write the spin hamilonien

3) to learn the parameters in the hamiltonien

4) to construct a basic ESR spectra

5) To understand the ESR in solid an d liquid

6) to have capability collect ESR spectrum


1. Apaydın, F. 1996, Magnetik Rezonans, H.Ü. Mühendislik Fakültesi Ders Kitapları, Ankara. 2. Poole, C.P. and Farach, H.A., 1972, The Theory of Magnetic Resonance, John Wiley, New York

3. Weil, J. A. and Bolton J. R. 1994, Electron Paramagnetic Resonance, John Wiley & Sons Inc., New

York

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Basic principal of Electron Spinc Resonance

Basic principal of Electron Spinc Resonance

Spin hamiltonien

Spin hamiltonien Spin hamiltonien

Isotropic hyperfine interaction

Zeeman interaction and g factors

Anisotropic hyperfine interaction

ESR in liquids ESR in liquids

ESR in single crystals

Exercise to construct a spectrum shape

Exercise to construct a spectrum shape

Relaxation times, linewidths and kinetic phenomena





Course Title: : Applications in Medical Physics of Photon Transport

Code : FFZ 5171



Lecture Application Lab. Project/ Field Study

Homework Other Total Credit T+A+L=Credit

ECTS

14x3=42 0 0 - 5x14=70 14x5=70 200 3 8

Semester Autumn/Sprin

g Language Turkish/English

Course Type


Technical Elective X

Social Elective

Course Objectives

Calculation of photon interaction coefficients of tissues and compounds and Monte Carlo applications


To calculate photon interaction coefficients in biological structures and to do simulations using the Monte Carlo method To detect abnormalities in the tissues


“Nuclear radiation physics”, Ralph E. Lapp and Howard L. Andrews “Exploring Monte Carlo Methods”, William L. Dunn and J. Kenneth Shultis “Sayısal çözümleme”, Recep Tapramaz

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Photon interference effects Elemental contents Form factors Scattering functions Photoelectric absorption cross section Coherent scattering cross section Incoherent scattering cross section Probability of photon interaction Linear attenuation coefficient Analysis of differential equations by numerical integration Monte Carlo applications Monte Carlo applications Monte Carlo applications Monte Carlo applications

Instructor/s Asist. Prof. Dr. Aysun BÖKE


Website


Course Title: Introduction to Density Functional Theory

Code : FFZ5172





ECTS

14x3=42 0 0 0 5x14=70 14x5=70

200 3 8


Course Type


Technical Elective

Social Elective

Course Objectives

To learn the fundamental concepts of Density Functional Theory.


The students taking the course will have a basic knowledge of the fundamental concepts of Density Functional Theory.


1. R. G. Parr, W. Yang, “Density Fuctional Theory of Atoms and Molecules”Oxford University Press, New york, 1989. 2. R. M. Martin, “Electronic structure”, Cambridge University Press, Cambridge, 2004.

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

The fundamental concepts in Quantum Mechanics The basic equations for electron-core interaction and Born-Oppenheimer Approximation The Coulomb interaction in condensed matter, Force and Stress Theorems Variation principle, correlation energy, electron density Wave function approximations, excahange and correlation Crystals, Reciprocal lattice, Brillouin zone Symmetry points and Integration of Brillouin zone Density Matrices and Introduction to Density Functional Theory (DFT) Thomas Fermi and Thomas Fermi Dirac models, Hohenberg-Kohn theorems Kohn-Sham orbitals and Derivation of Kohn-Sham equations Spin DFT and functionals, Local spin density approximations Exchange correlation hole, Functionals for exchange correlation Solution of Kohn-Sham equations Solution of Kohn-Sham equations

Instructor/s Doç. Dr. Cansu ÇOBAN


Website

X


Course Title: Biomolecular Films on Biosensors

Code : FFZ5173





ECTS

42 - - - - - 42 3 8

Semester Autumn/Spring Language Turkish

Course Type


Technical Elective

Social Elective

Course Objectives

Teaching the techniques, design, and applications of biomolecular fi lms on biosensors .


Be able to describe basic properties of biomolecular films on biosensor design, gain an ability to explain various biomolecular films and their construction on biosensors, Be able to design and developed biomolecular films for different biosensor applications.


Rusling,J.F., Biomolecular Films: Desing, Function and Application,CRC, 2003 Sadana,A., Engineering Biosensors;Kinetic and Desing Applications,Academic Press, 2001

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)

Midterm Exams 1 40 Midterm Exams

Quizzes - Midterm Controls

Homework - Term Paper


- Oral Examination

Laboratory Work - Final Exam

Final Exam 1 60 Other

Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13

14

Methods of thin films formation, Methods for the examination of the thin films, Biologically active films, Nanotechnology and biosensors, Practical physical aspects of interfacial nucleic acid oligomer hybridisation for biosensor design, Plasma polymerized films for biosensors, Self-assembled monolayers as a adjusted platform for biosensor applications , Design and performances of immunoassay based on SPR biosensor with magnetic microbeads , Electrochemical biosensor design and construction, Materials and techniques for electrochemical biosensor design and construction, Structural analysis of carbon nanotubes -ionic liquid gel biosensor, Analysis of carbon nanotubes-ionic liquid gel biosensor Electrochemistry of supported bilayer lipid membranes: background and techniques for biosensor, Evaluation, comprehension and comparison of techniques .

Instructor/s Assist. Prof. Dr. Tayfun UZUNOĞLU


Website


Course Title: Structures and properties of solids I

Code : FFZ5174




T+A+L=Credit ECTS

14x3=42 0 0 0 5x14=70 14x5=70

200 3 8


Course Type


Technical Elective

Social Elective

Course Objectives

To learn the fundamental concepts of Solid state physics.


The students taking the course will have a basic knowledge of the fundamental concepts of Solid state physics.


1. J.R.Hook, H.E.Hall, Solid State Physics'' 2. C. Kittel ''Introduction to Solid State Physics''

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Interatomic bonds '' '' Crystals and Crystallizing solids '' '' Mechanical properties of solids '' '' '' Electrical properties of metals '' '' ''



Website

X


Course Title: Electromagnetic Theory I Code : FFZ 5175





ECTS

14x3= 42 0 0 - 5x14= 70 14x5=70 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

Learning in detail the Electrostatic and magnetostaic subjects


1) To learn basic concepts of Electrostatic 2) To solve problems using Gauss law 3) To be use Poisson and Laplace equations in problem solutions 4) To solve Boundary-Value Problems 5) Using Gren fonction in solving electrostatic problems 6) To undersand the properties of Dielectrics 7) To learn Magnetostatic 8) To undestand the important of Maxwell equations 9) Learning the vector potential


1. J.D. Jackson, "Classical Electrodynamics", John & Sons, Inc., (1975). 2. G.L. Pollack, D.R. Stump, ''Elektromanyetik Teori'', Gazi Kitapevi, (2004). 3. D.J. Griffiths, "Elektromagnetik Teori", ARTe Reklamcılık ve Tanıtım Ltd. Şti., (1996).

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction to Electrostatics Gauss’s Law Poisson and Laplace Equations Boundary-Value Problems in Electrostatics I Method of Image charge Different Charges Problems Conducting Sphere and Green Function Boundary-Value Problems in Electrostatics II Laplace and Legendre Equation Multipoles, Electrostatics of Macroscopic media, dielectrics Magnetostatics Vector Potenial Maxwell equations, conservation laws Plane electromagnetic waves and wave propagation

Instructors Yrd.Doç.Dr. Remziye TÜLEK


Website


Course Title : Superparamagnetism in Magnetic Nanoparticles

Code : FFZ5176

Institute: Institute of Science Field : Physics


Lecture Application Lab. Project/Field Study


ECTS

3x14=42 5x14=70 5x14=70 200 3 8



Technical Elective

Social Elective

Course Objectives

Teaching the properties of magnetic nanoparticles

Teaching the basic fundamental knowledge about superparamagnetism


1) Describin g the magnetic nanoparticles

2) Understanding the magnetic properties of magnetic nanoparticles and superparamagnetism


1) Klabunde K. J., Nanoscale Materials in Chemistry, John Wiley & Sons, Inc.,New York, (2001 )

2) Edelstein A. S., Cammarata R. C., Nanomaterials: Synthesis, Properties and Applications, Institute of

Physics Publishing, Bristol, (2002)

3) Baraton M.I., Synthesis, Functualization and Surface Treatment of Nanoparticles, American Scientific

Publishers, USA, (2003)

4) D. Jiles, “Introduction to Magnetism and Magnetic Mat erials”, Chapman & Hall, London

5) R. M. Bozorth “Ferromagnetism”, D: Van Nostrand Company Inc. Princeton

6) C. Kittel, “Introduction to Solid State Physics” İngilizce 6. baskıdan çeviri, Türkçesi: B. Karaoğlu,

Güven Kitap Yayın Dağıtım Ltd. Şti

7) D. Craik, “Magnetism Principles and Applications”, Universtiy of Nottingham

ASSESSMENT CRITERIA


If any, mark as

(X) Percent (%)

If any, mark as (X)

Percent (%)



Homew ork X %20 Term Paper

Term Paper, Project

Reports, etc. Oral Examination


Final Exam X %80 Other

Other

Week Subjects

1

2 3 4 5

6 7 8 9

10 11 12 13

14

Introduction

Origin of magnetism Fundamental definations in magnetism Theory of Diamagnetism Theory of Paramgnetism

Ferromagnetism Antiferromagnetism Ferrimagnetism Magnetic domains

Single domain magnetism Superparamagnetism Superparamagnetism in nanoparticles Types of magnetic nanoparticles

Applications of magnetic nanoparticles

Instructor/s Assoc. Prof. Dr. Öznur KARAAĞAÇ


Website


Course Title: Design of Biosensors and its applications

Code : FFZ5177




T+A+L=Credit ECTS

42 - - - - 42 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

Emphasizing the importance of biosensors in our daily lives, and they understand the basic principles for their design. This course is produced in accordance with the intended use of the biosensor with them and learn to be designed to be used in daily life.


Be able to describe the most common sensor principles, Be able to have a broad understanding of the applications of various sensors and transducers for various measurements, Gain an ability to design and developed biosensors for different applications, Be conversant in biosensor design and which parameters will influence biosensor performance, Be able to evaluate critically on new biosensor technologies presented in the literature.


Enzyme and Microbial Biosensors”, Humana Press Inclined, (1998) A. Telefoncu (Ed.), “Biyosensorler”, Ege Universitesi, (1999) T. M.Canh,”Biosensors” Chapman and Hall, (1993)

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





- Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Overview of biosensors, A brief history of biosensors , Biosensors according to the species that forming signal, Biomolecules used in biosensors , Classifications of Biosensors Properties of Biosensors Characteristics of biosensors Electrochemical biosensors, Optic biosensors, Thermal biosensors, Piezoelectric biosensors, SPR based biosensors, Performans factors of biosensors, Use and applicatios of biosensors



Website


Course Title : Functional Magnetic Nanoparticles

Code : FFZ5178

Insttute: Institute of Science Field : Physics




ECTS

3x14=42 5x14=70 5x14=70 200 3 8

Semester Spring Language Turkish/English


Technical Elective

Social Elective

Course Objectives

Teaching the properties of functionalized magnetic nanoparticles


3) Recognizing the properties of functionalized magnetic nanoparticles








12) J.P. Jolivet, “Metal oxide chemistry and synthesis, From solution to solid state”, John Wiley & Sons,

Inc.,London, (2003)

ASSESSMENT CRITERIA


If any, mark as

(X) Percent (%)

If any, mark as (X)

Percent (%)



Homew ork Term Paper


X %20 Oral Examination



Other

Week Subjects

1 2

3 4 5 6

7 8 9 10

11 12 13 14

Introduction Properties of magnetic nanoparticles

Magnetic metal nanoparticles Magnetic metal oxide nanoparticles Magnetic alloy nanoparticles Core-shell structures

Oxide layer coated magnetic nanoparticles Silica coated magnetic nanoparticles Carbon coated magnetic nanoparticles Precious metal coated magnetic nanoparticles

Polymer coated magnetic nanoparticles Surfactant coated magnetic nanoparticles Surface properties of magnetic nanoparticles Surface properties of coated magnetic nanoparticles



Website


Course title : QUANTUM MECHANICS II

Code : FFZ 5203



Field Study

Homework


ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Electrive

Course Objectives

The aim of the course is to introduce quantum mechanics in the graduate level.


To calculate the effect of perturbation to states and energies of a bound system, To calculate the differential cross-section for a given scattering process, To obtain the relativistic quantum mechanical solution for scalar and spin-1/2 particles.


[1] J.J. Sakurai “Modern Quantum Mechanics”, Addison-Wesley, 1994 [2] Other quantum mechanics books in graduate level

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Time independent perturbation theory Application to hydrogenlike atoms : Fine structure and Zeeman effect Interaction picture and time dependent perturbation theory Interaction of particles with classical electromagnetic radiation Identical particles Scattering theory; Born approximation; Optical theorem; Eikonal approximation Method of Partial Waves; Low-energy scattering and bound states Resonance scattering; Identical particles and symmetry in scattering Time-dependent formulation of scattering Coulomb scattering 4-vectors; Lorentz gauge; Lorentz invariant form of Maxwell equations Klein-Gordon equation Dirac equation





Course title: Advance Molecular Physics Code: FFZ 5204





ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

Introduction to molecular physics and its applications


1) To understand molecular physics 2) To solve Schrödinger Equation for molecules contains two atoms 3) To learn energy spectrum of molecules 4) To learn molecular orbital theory 5) To understand the spectroscopic methods for molecular physics


[1] Atom ve Molekül Fiziği , B. H. Bransden C.J. Joachain, Translate editor: Prof. Dr. Fevzi Köksal 1989, Samsun University [2] Atom ve Molekul Fizigi, Erol Aygun, Mehmet Zengin, Bizim Büro, Ankara. [3] Modern Fiziğin Kavramları, Arthur Beiser, Çeviren: Gülsen Önengüt, Akademi yayıncılık, Ankara. [4] Atomlar ve Moleküller, M.Ayhan Zeren, Birsen Yayınevi.

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction of molecular physics and structure of molecules Structure of molecules Molecules with two atoms and Schrödinger wave function Molecules with two atoms and energy levels Molecular systems with many atoms Molecular energy levels Molecular Orbital Theory Molecular spectroscopy Microwave spectroscopy in molecular physics and its applications Infrared spectroscopy in molecular physics and its applications UV-visible spectroscopy in molecular physics and its applications Electrical and magnetic properties of molecules Optical properties of molecules Structural properties of molecules





Course title: Langmuir-Blodgett Thin Film Technology II

Code: FFZ 5209





ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To characterize the Langmuir-Blodgett thin films using the spectrocipic methods


1) To learn optical properties of LB films 2) To learn electrical properties of LB films 3) To learn structural and magnetic properties of LB films 4) To learn the application of LB films in spectroscopy


[1] Langmuir-Blodgett Films, Michael C. Petty, 1996, Cambridge Press. [2] Langmuir-Blodgett Films, by G. Roberts, 1990, Springer, New York. [3] An Introduction to Ultra thin Organic Films: From Langmuir-Blodgett to Self-Assembly, A. Ulman, 1991, Academic Pres.

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Physical Properties of Langmuir-Blodgett (LB) Thin Films Electrical Properties of LB films Optical Properties of LB films Structural Properties of LB films Magnetic Properties of LB films Application of LB films in industry Analysis of LB films using spectroscopic methods X-Rays in LB films UV-visible method in LB films FTIR method in LB films Applied of QCM method in LB films Applied of SPR method in LB films Applied of AFM method in LB films LB films in security systems and their applications in electronics





Course title : : Mathematical Methods in Physics II

Code : FFZ 5211



n Laboratuary Project/


redit ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8




Social Electrive

Course Objectives

Development and Applications of Mathematical Postulates In Order to Solve the Theoretical Physics Problems


Knowlege and Application of Mathematical Tolls to Physical Problems


[1] Mathematical Methods for Physicsist , George Arfken, Academic Press [2] Mathematical Physics, Eugene Butkov, Addison Wesley [3] Fen ve Mühendislik Bilimlerinde Matematik Yöntemler, Selçuk Bayın, Metu Press

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Bessel Functions and Orthogonality First-kind Bessel Functions and Neumann Functions Second-kind Bessel Functions and Hankel Functions Modified Bessel Functions Legendre Functions Unified Legendre Functions Spherical Harmonics Orbital Angular Momentum Operators Introduction to Special Functions Beta Functions and Gamma Functions Hermite Functions Laguerre Fuctions Chebyshev (Tschebyscheff) Polynomials Hyper-geometrics Functions

Instructors Assoc. Prof. Matem ERDOĞAN


Web Address



Course title: Spectroscopic Methods II Code: FFZ 5213 Institute: Science Field: Physics

Education and Teaching Methods Credits Lecture Application Laboratory Project/



ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific

Compulsory

Technical Elective

Social Elective

Course Objectives

To introduce luminesans, Atomic Force Microscopy and Scanning Tunneling Microscopy


1) To learn Luminesans spectroscopy 2) To learn Atomic Force Microscopy 3) To learn Scanning Tunneling Microscopy


1) Enstrümantal Analiz Yöntemleri, Prof. Dr. Atilla Yıldız, Prof. Dr. Ömer Genç, Prof. Dr. Sema Bektaş, Hacettepe Üniversitesi Yayınları 2) Atomic Force Microscopy/Scanning Tunneling Microscopy, M.T. Bray (Editor), Samuel H. Cohen (Editor), Marcia L. Lightbody,

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Principles of Fluorescence and phosphorescence spectroscopy Measurement systems of Fluorescence and phosphorescence spectroscopy Fluorescence and phosphorescence spectra Analysis of Fluorescence and phosphorescence spectra Applications of Fluorescence and phosphorescence spectroscopy Principles of Atomic Force Microscopy Measurement systems of Atomic Force Microscopy Atomic Force Microscopy Images Analysis of Atomic Force Microscopy Images Applications of Atomic Force Microscopy Principles of Scanning Tunneling Microscopy Measurement systems of Scanning Tunneling Microscopy Scanning Tunneling Microscopy Images Analysis of Scanning Tunneling Microscopy Images




http://www.amazon.com/exec/obidos/search-handle-url/ref=ntt_athr_dp_sr_2?%5Fencoding=UTF8&search-type=ss&index=books&field-author=Samuel%20H.%20Cohen

http://www.amazon.com/exec/obidos/search-handle-url/ref=ntt_athr_dp_sr_3?%5Fencoding=UTF8&search-type=ss&index=books&field-author=Marcia%20L.%20Lightbody


Course title: Molecular Electronics II Code: FFZ 5214 Institute: Science Field: Physics




ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To introduce the techniques used in Molecular Electronics and its applications


1) To learn film preparation techniques in Molecular Electronics 2) To learn applications of Molecular electronics


Introduction to Molecular Electronics Edited by M. C. Petty, M. R. Bryce, and D. Bloor (University of Durham, U.K.). Oxford University Press: New York. 1995.

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Thin film techniques used in molecular electronics Spin Coating Langmuir-Blodgett Thin Film Technique Evaporation Method Measurement techniques in molecular electronics Electric Measurement systems IV, Cf, CV measurements Analysis of measurements Application of molecular electronic devices Heat sensors and their applications Biosensor and its applications Gas sensors and their applications The application of optoelectronic devices in molecular electronics General outcomes





Course title: Modern Quantum Concepts II Code: FFZ 5215 Institute: Science Field: Physics




ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To obtain detail information regarding to quantum mechanics


1- Knowledge of the theoretical approaches used in quantum mechanics 2- An understanding of the quantum mechanics


1- Modern Fiziğin Kavramları, A. Beiser 2- Modern Quantum Mechanics (revised edition), J.J. Sakurai, Addison-Wesley 1994

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction Atomic Hamiltonian Eigen function Operators Operators Symmetry and transformation Identical particles Heat capacity Molecules Statistical mechanics Quantum statistics Quantum statistics Atomic Particles Crystal and amorf structures






Course title: Advanced Surface Physics II Code: FFZ 5216 Institute: Science Field: Physics




ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives



1- Knowledge of the theoretical and experimental approaches used in surface physics 2- An understanding of the surface physics


1- “Surface Science”, K. O URA, V.G. Lifshits, A.A. Zotov and M. Katayama, Springer 2003. 2- “Introduction to Surface Physics”, M. Prutton, Oxford Science Publications 1997.

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Surface analysis I: Diffraction Methods Surface analysis I: Diffraction Methods Surface analysis II: Electron spectroscopy methods Surface analysis II: Electron spectroscopy methods Surface analysis III: Probing surfaces with ions Surface analysis III: Probing surfaces with ions Surface analysis IV: Microscopy Surface analysis IV: Microscopy Atomic structure of clean surfaces Atomic structure of surfaces with adsorbates Structural defects at surfaces Electronic structure of surfaces Growth of thin films Growth of thin films






Course Title: Classical Mechanics Code : FFZ 5219 Institute: Science Field: Physics

Education and Teaching Methods Credits Lecture Applica

tion Laboratuary Project/


Other Total

T+A+L=Credit

ECTS

14x3=42 4x14=56 14x5=70 200 3 8

Semester Spring Language Turkish

Course Type

Basic Scientific


Social Elective

Course Objectives

To give intermediate level mechanics


To have an strong basis for advanced and pure physics


Herbert Goldstein

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)

Midterm Exams x 25 Midterm Exams


Homeworks x 15 Term Paper


Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Survey of the elementary principles Variational principles and Lagrange’s equations The two-body central force problem The kinematics of rigid body motion The Rigid body equations of motion The Rigid body equations of motion Special relativity in classical mechanics Special relativity in classical mechanics The Hamilton eqautions of motion Canonical transformations Hamilton-Jacobi theory Small Oscillations Canonical Perturbation theory Introduction to the Lagrangian and Hamiltonian formulations for continuous systems and fields

Instructors Assoc. Prof. Dr. Sibel Gökden




Course Title Crystal structure analysis Code : FFZ 5220 Institute: Science Field: Physics

Education and Teaching Methods Credits Lecture Application Laboratuar

y Project/



ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course type Basic field course

Field Course

Technical Elective

Social Elective

Course Objectives

To develop strong background for the crystal structure analysis.


To learn solution and refinement of crystal structures



ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)








Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Solution and refinement of crystal structures Statistical analysis of structure factor amplitudes Patterson function and its use The heavy atom model Advanced Patterson method Direct methods Structure invariants and semi-invariants Probability methods Completing and refining the structure Difference Fourier method Least square method Absolute configuration Practice “





Course title : OPTOELECTRONICS II

Code : FFZ 5222





ECTS

14x3=42 0 0 - 5x14=70

88 200 3 8


Course Type

Basic Scientific


Social Electrive

Course Objectives

The purpose of this course is to know and learn the semiconductor optoelectronic devices and their operational principles. It is also desired to research the applications areas.


1) To learn the photodetector structures, operational principles and application areas 2) To learn the light emitting diode structures, operational principles and application areas 3) To learn the semiconductor laser structures, operational principles and application areas 4) To learn the solar cell structures, operational principles and application areas 5) To learn the optical modulator structures, operational principles and application areas 6) Fiber-optic communication technology


[1] Jasprit Singh “Semiconductor Optoelectronics , Physics and Technology”, 1995, McGraw-Hill, New Jersey [2] Pallab Bhattacharya “Semiconductor Optoelectronic Devices” 1996, Prentice Hall, New Jersey

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Semiconductor p-n junction Semiconductor p-n junction Optoelectronic detectors Noise in detectors Light emittng diodes Light emittng diodes Semiconductor laser diodes Semiconductor laser diodes Solar Cells Optoelectronic modulators and applications Fiber-optics communication technologies Fiber-optics communication technologies Organic semiconductor technologies Organic light emitting devices





Course title: Technology of Vacuum II Code: FFZ 5224 Institute: Science Field: Physics




ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To obtain detail information regarding to technology of vacuum


1- Knowledge of the theoretical and experimental approaches used in technology of vacuum 2- An understanding of the technology of vacuum


1- “Modern Vacuum Practise”, N. Harris, Mc Graw Hill. 2- “Basic Vacuum Practice”, Varian Vacuum Products Division.

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Identification of gases present Identification of gases present Oil-sealed mechanical rotary pumps Oil-sealed mechanical rotary pumps Oil-free mechanical primary pumps Oil-free mechanical primary pumps Diffusion pumps and accessories Diffusion pumps and accessories Turbomolecular pumps Turbomolecular pumps Cryopumps Cryopumps Vacuum pump comparisons Vacuum system connections and components






Course Title: Magnetic Domains and Their Observation Techniques




Credit ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

Observation of magnetic domains to understand magnetic characteristics of ferromagnetic materials






Willey&Sons, USA, 2000, pp 740. 7. Richard M. Bozorth “Ferromagnetism”, IEEE Press, USA, 1993, pp. 968. 8. Alex Hubert, Rudolf Schafer, “Magnetic Domains” , Springer, Germany, 1998, pp. 696. 9. B.D. Cullity, “Introduction to Magnetic Materials”, Adisson-Wesley Pub.Co., 1972, pp. 666.

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction to magnetic domain theory Properties of ferromagnetic domains Investigation of energy in magnetic domains Influence of magnetic field on magnetic domains Investigation of the magnetic domains in sensor cores Influence of stress on magnetic domains Bitter colloid technique Kerr effect Sample preparation techniques for domain observation Properties of the Kerr bench Domain observation by using SEM Observation of static magnetic domains on SiFe Observation of magnetic domains on amorphous magnetic materials Introduction to magnetic domain theory





Course Title: Magnetic Measurement Systems Code : FFZ 5226 Institute: Science Field: Physics




ECTS

14x3=42 0 0 - 5x14=70

88 200 3 8


Course Type


Technical Elective

Social Elective

Course Objectives

Investigation of magnetic measurement systems






Willey&Sons, USA, 2000, pp 740. 7. Richard M. Bozorth “Ferromagnetism”, IEEE Press, USA, 1993, pp. 968. 8. Alex Hubert, Rudolf Schafer, “Magnetic Domains” , Springer, Germany, 1998, pp. 696. 9. B.D. Cullity, “Introduction to Magnetic Materials”, Adisson-Wesley Pub.Co., 1972, pp. 666.

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction to fundamental magnetic measurement systems Measurements of electrical resistance Signal processing techniques Magnetic field measurements Investigation of the magnetic sensor characteristics Operational amplifiers Investigation of characteristics on operational amplifiers Kerr effect technique Investigation of Kerr effect and Kerr bench systems Active and passive sensors Investigation of the negative feedback on magnetic measurement systems Analogue / Digital – Digital / Analogue (ADDA) converters Investigation of the data collection by using parallel and serial ports Control of stepper motors by using parallel port





Course title: Surface Science Techniques II Code: FFZ 5227 Institute: Science Field: Physics




ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To learn surface science techniques


1- Knowledge of the experimental techniques used in materials characterization. 2- An understanding of the most common surface science techniques


1- “Handbook of Surface and Interface Analysis”, Edited by: J.C. Rivière and S. Myhra, Publisher: Marcel Dekker Inc. 2- “Methods of Surface Analysis”, Edited by: J.M. Walls, Cambridge University Press

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Methods of surface analysis In-depth analysis methods Reflection anisotropy spectroscopy Magnetic liner dichrosim in angular dependence – Magnetic circular dichrosim Temperature programmed techniques Mösssbauer spectroscopy Low energy electron diffraction Infrared spectroscopy Raman spectroscopy Electron energy loss spectroscopy Extended X-ray adsorption fine structure Angle-resolved ultraviolet photoelectron spectroscopy Ion erosion in surface analysis Electron and ion energy analysis






Course title: Surface Physics of Semiconductor II





ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives



1- Knowledge of the experimental techniques used in semiconductors. 2- An understanding of the semiconductors.


1- Dr. Ceyhun Bulutay, “Electronic and Optical Processes in Semiconductors” lecturer notes, Bilkent University (obtained permission from author using these notes)

2- Kittel C., “Introduction to Solid State Physics”, Türkçesi Karaoğlu B., Güven Yayıncılık, İstanbul, 1996.

3- Morgan D. V., Moses A. J., “III-V Quantum System Research”, Peter Peregrinus Ltd, London, 1995

4- Biasiol G. , Sorba L.,“Molecular Beam Epitaxy: Principles and Applications”, Eds, Edizioni ETS, Pisa, 2001 5- Singleton J., “Bant Theory and Electronic Properties of Solids”, Oxford University Press, Great Britain, 2003.

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Basic semiconductor culture and review of crystal structure Basic semiconductor culture and review of crystal structure Review of crystal structure and semiconductor band structure Semiconductor band structure Semiconductor band structure Alloys, heterostructures and superlattices Alloys, heterostructures and superlattices Superlattices and strain effects Lattice vibrations Lattice vibrations Semiclassical transport and coherent transport Coherent transport and optical processes Optical processes Optical processes






Course title: PRODUCTION AND CHARACTERISATION TECHNIQUES OF FERROMAGNETIC FILMS

Code: FFZ 5232





ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific

Scientific

Technical Elective

Social Electrive

Course Objectives

Investigation of Characterisation techniques and Production methods of ferromagnetic films


Production of thin f ilms, alloys and multilayer Thermal evaporation technique dc sputtering technique Elektrodeposition technique

Elektrodeposition technique Magnetic characterisation techniques, induction techniques Manyeto-optik kerr effect (MOKE)

Vibrating sample magnetometer (VSM) Magneto-resistance (MR) measurements The other methods depending on changes in their material properties Structural characterisation techniques

X-ray diffraction (XRD) Scanning electron microscopy (SEM) Transmission electron microscopy (TEM)


[1] D. Craik, “Magnetism Principles and Applications”, Universtiy of Nottingham. [2] R. M. Bozorth “Ferromagnetism”, D: Van Nostrand Company Inc. Princeton. [3] D.J. Maps, “Applications in Magnetic Recording”, School of Electronic, Communication and Electrical Engineering, University of Plymouth. [4] D. Jiles, “Introduction to Magnetism and Magnetic Materials”, Chapman & Hall, London

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Production of thin films, alloys and multilayer Thermal evaporation technique dc sputtering technique Elektrodeposition technique Elektrodeposition technique Magnetic characterisation techniques, induction techniques Manyeto-optik kerr effect (MOKE) Vibrating sample magnetometer (VSM) Magneto-resistance (MR) measurements The other methods depending on changes in their material properties Structural characterisation techniques X-ray diffraction (XRD) Scanning electron microscopy (SEM) Transmission electron microscopy (TEM)



Web Address


Course title: MATERIAL PHYSICS AND APPLICATIONS





ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Electrive

Course Objectives

Physical properties of materials and their applications


Inner structure of materials Crystal Amorphous structure Solid solutions Formation of inner structure Phase transformations and phase diagrams Material properties Electrical conduction Semiconductors Dielectric properties Magnetic properties Optical properties, thermal properties Industrial materials; metals, plastics Ceramics, composite materials, colloidal matters


H. Kockar, Materials lecturer handouts, 2001.

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Inner structure of materials Crystal Amorphous structure Solid solutions Formation of inner structure Phase transformations and phase diagrams Material properties Electrical conduction Semiconductors Dielectric properties Magnetic properties Optical properties, thermal properties Industrial materials; metals, plastics Ceramics, composite materials, colloidal matters



Web Address


Course Title: Physics of Semiconductors and

Their Heterostructures –II Code : FFZ 5237

Institute: Science

Field: Physics



Other Total

Credit T+A+L=Credit

ECTS

14x3= 42 0 0 - 5x14= 70 14x5=70 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

Trans port, electrical and optical properties in heterostructures and semiconductors


to have adequate information about the properties of electrical, optical and transport of heterostructures and semiconductors


All books of semiconductors and lecture notes

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 The velocity field relations, Transport in heterostructures,

2 Interactions of photons with semiconductors

3 Optical properties in semiconductors excitonic transitions

4 Semiconductors in magnetic fields

5 Defects and disorder in semiconductors

6 Growth techniques, Microfabrication in Semiconductors

7 Semiconductor homojunctions and heterojunctions

8 Low dimensional semiconductors, The two dimensional electron gas

9 Hot electrons

10 Scattering mechanisms

11 Electrical Measurement Techniques: Hall Effect, I-V measurements

12 SdH measurements

13 Optical Measurement Techniques: Photoluminescence

14 and Electroluminescence

Instructors Assoc. Prof. Dr. Sibel Gökden

e-mail [email protected] Website w3.balikesir.edu.tr/sozalp


Course Title: CALCULATION AND SIMULATION II

Code : FFZ 5239






ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific

Scientific

Technical Elective

Social Elective

Course Objectives

To learn the basic concepts of numerical calculation at physics under grade’s degree


To learn the Numerical derivation To learn the Numerical integration To learn the Fourier series, To learn the calculation of the differential equation, To learn the computation of the partial differential equations To learn the data operations.


[1] Tapmaz, Recep, Sayısal Çözümle, Literatür Yayıncılık, 2002, İstanbul. [2] Karagöz, İhsan, Sayısal Analiz ve Mühendislik Uygulamaları, UÜ Güçlendirme vakfı Yayını,2001,Bursa. [3] I. S. Skolnikoff, R. M. Redheffer, Mathematics of Physics and Modern Engineering, 1966.

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Numerical derivation I Numerical derivation II Numerical integration I Numerical integration II Numerical integration III Fourier series I Fourier series II Difference equation calculation I Difference equation calculation II Partial differential equations I Partial differential equations II Partial differential equations III Data operation and analysis I Data operation and analysis II



Web Address



Course title: Advanced Condensed Matter Physics II





ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To obtain detail information regarding to condensed matter physics.


1- Knowledge of the theoretical and experimental approaches used in condensed matter physics 2- An understanding of the condensed matter physics


1- “Introduction to Solid State Physics”, C. Kittel, Seventh Edition, John Wiley and Sons Inc. 1996. 2- “Katıhal fiziğine giriş”, M. Dikici, Ondokuz Mayıs Üniversitesi, Samsun, 1993.

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Phonons I. Crystal vibrations Phonons II. Thermal properties Free electron Fermi gas Free electron Fermi gas Energy bands Energy bands Semiconductor crystals Semiconductor crystals Fermi surfaces and calculation of energy bands Fermi surfaces and calculation of energy bands Plasmons, polaritons, and polarons Optical processes and excitons Noncrystalline solids Surfaces and interface physics






Course title: PHYSICS OF MAGNETIC MATERIALS

Code: FFZ 5243




redit ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type


Technical Elective

Social Electrive

Course Objectives

Quantum mechanical explanation of magnetic materials


Atomic magnetisation Langevin theory of diamagnetism Langevin localized theory of paramagnetism, Pauli paramagnetism

Ferromagnetism and Weiss-theory, itinerant ferromagnetic theory Antiferromagnetism, ferrimagnetism Magnetic anisotropy Magnetisation process, hysteresis loops

Description of energy minimisation for the formation of domain and domain w all in SiFe magnetic material Magnetostriction Pow er loss in magnetic materials together with their causes Temperature dependence of magnetism

Nuclear magnetisation Nuclear magnetic scattering Magnons



ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination

Laboratory Work Final Exam Final Exam X 60 Other

Other

Week Subjects

1 2 3 4 5 6 7 8

9 10 11 12 13 14

Atomic magnetisation Langevin theory of diamagnetism Langevin localized theory of paramagnetism, Pauli paramagnetism Ferromagnetism and Weiss-theory, itinerant ferromagnetic theory Antiferromagnetism, ferrimagnetism Magnetic anisotropy Magnetisation process, hysteresis loops Description of energy minimisation for the formation of domain and domain wall in SiFe magnetic material Magnetostriction Power loss in magnetic materials together with their causes Temperature dependence of magnetism Nuclear magnetisation Nuclear magnetic scattering Magnons



Web Address


Course Title: Quantum Field Theory-II

Code : FFZ 5246





ECTS

14x3=42 0 0 - 5x14=70

88 200 3 8

Semester spring Language Turkish/English

Course Type


Technical Elective

Social Elective

Course Objectives

- Introducing students to advanced topics of QFT.


The student must be able to : - calculate any process in QFT.


An Introduction to Quantum Field Theory Michael E. Peskin & Daniel V. Schroder Addison-Wesley ISBN 0-201-50397-2

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Radiative Corrections Radiative Corrections Renormalization Renormalization The Coleman-Weinberg Potential Non-Abelian Gauge Theories Non-Abelian Gauge Theories Quantum Chromodynamics Quantum Chromodynamics -Deep Ineastic Scattering Hard Scattering Processes Operator Product Anomalies Spontaneous Symmetry Breaking Spontaneous Symmetry Breaking

Instructors Assoc. Prof. Dr. Levent SOLMAZ




Course title : SURFACE PLASMON RESONANCE TECHNIQUE AND ITS APPLICATIONS



n Laboratory Project/


redit ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8




Social Electrive

Course Objectives

To obtain knowledge on Surface Plasmon Resonance Technique and its applications


The investigation of the Surface Plasmon Resonance Technique and its applications


Surface Plasmon Resonance Technique books

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)








Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction Experimental set up of the Surface Plasmon Resonance Technique Refractive index of the thin films Working Principles of the Surface Plasmon Resonance Technique Working Principles of the Surface Plasmon Resonance Technique Working Principles of the Surface Plasmon Resonance Technique Surface Plasmon Resonance curves Surface Plasmon Resonance curves Thickness calculations using Surface Plasmon Resonance Technique Thickness calculations using Surface Plasmon Resonance Technique Gas sensing applications using Surface Plasmon Resonance Technique Gas sensing applications using Surface Plasmon Resonance Technique Gas sensing applications using Surface Plasmon Resonance Technique Gas sensing applications using Surface Plasmon Resonance Technique






Course title : ORGANIC THIN FILM CHARACTERISATION TECHNIQUES

Code : FFZ 5248




redit ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8




Social Electrive

Course Objectives

To obtain knowledge on organic Thin Film Characterisation Techniques


Learning the Thin Film Characterisation Techniques


Books on the Thin Film Fabrication and Characterisation Techniques

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)








Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction Parameters to analise the thin film properties Thickness characterisation techniques (Ellipsometry, UV) Thickness characterisation techniques (Ellipsometry, UV) Thickness characterisation techniques (Ellipsometry, UV) Characterisation of the surface properties Characterisation of the surface properties (AFM, STM) Characterisation of the surface properties (AFM, STM) Characterisation of the electrical properties Characterisation of the electrical properties Characterisation of the electrical properties Characterisation of the optical properties Characterisation of the optical properties Characterisation of the optical properties






Course Title: Many Particle Theory II Code : FFZ 5249 Institute: Science Field: Physics



Credit ECTS

14x3=42 0 0

- 5x14=70 88

200 3 8


Course Type

Compulsory Area Technical Elective

Social Elective

Course Objectives

The aim of the course is to introduce condensed matter theory based on the principles of many particle physics in the graduate level.


The student will gain the necessary tools to pursue his/her own research in condensed matter physics.


Many-Body Theory of Solids, J.C. Inkson, Plenum Press, 1984. Many-Particle Physics, G.D. Mahan, Plenum Press, 1990.

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)






Laboratory Work -- -- Final Exam


Other -- --

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Properties of the electron gas Sum rules One-electron properties of the electron gas Electron-phonon ineractions Polarons Optical properties of solids Nearly free electron system Wannier excitons X-ray spectra in metals Properties of superconductors BCS theory of superconductivity Electron tunneling Ginzburg-Landau theory Superconductivity in thin films





Course Title: Magnetic Resonance II

Code : FFZ 5250





ECTS

14x3=42 0 0 - 5x14=70

88 200 3 8


Course Type


Technical Elective

Social Elective

Course Objectives

To understand the Electron Spin Resonance technique and theory


1) To learn basic concepts of Electron spin resonance 2) to learn operator, eigenvalue, and eigenfunctions 3) to learn dirac notation and matrix elements 4) to write the spin hamilonien 5) to learn the parameters in the hamiltonien 6) To understand the ESR in solid and liquid 7) to learn the double resonance (ENDOR) technique 8) to have capability collect ESR spectrum


4. Apaydın, F. 1996, Magnetik Rezonans, H.Ü. Mühendislik Fakültesi Ders Kitapları, Ankara. 5. Poole, C.P. and Farach, H.A., 1972, The Theory of Magnetic Resonance, John Wiley, New

York 6. Weil, J. A. and Bolton J. R. 1994, Electron Paramagnetic Resonance, John Wiley & Sons

Inc., New York

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Basic principal of Electron Spinc Resonance Quantum Mechanical Process Operators, eigenvalue, eigenfunction Dirac notation and matrix component Magnetic interaction between the particles Spin hamiltonien Isotropic hyperfine interaction Zeeman interaction and g factors Anisotropic hyperfine interaction Spin system have more than one spin ESR in liquids ESR in single crystals Double resonance (ENDOR) Relaxation times, linewidths and kinetic phenomena





Course title : QUANTUM ELECTRONICS II Code : FFZ 5251





ECTS

14x3=42 0 0 - 5x14=70

88 200 3 8




Social Electrive

Course Objectives

To learn the main principles involved in the study and practice of quantum electornics such as the theory of laser oscillation, wide range of optical phenomena and devices


Lasers, nonlinear optical effcets and stimulated scattering phenomena, optical modes and propagation phenomena


[1] Ammon Yariv “ Quantum Electronics” 1989, John Wiley & Sons Inc

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Laser oscillation Some specific laser systems Semiconductor diode laser Quantum well laser The free-electron laser The modulation of optical radiation Coherent interactions of a radiation field and an atomic system Introduction to nonlinear optics -Second harmonic generation Parametric amplification, oscillation and fluorescence Third order optical nonlinearities - Stimulated Raman and Brillouin scattering Phase-conjugate-optics and photorefractive beam coupling Q-switching and mode locking of lasers Noise and spectra of laser amplifiers and oscillators Guided wave optics-Propagation in optical fibers





Course Title Magnetic properties of solids II - Code : FFZ 5252 Institute: Science Field: Physics




ECTS

14x3=42 0 0 - 5x14=70

88 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To develop strong background for the magnetic properties of solids


To learn Magnetization and magnetic susceptibility To learn Isotropic interaction in polynuclear compounds


Molecular magnetism ( Olivier Kahn) Molecular Magnetism: New Magnetic Materials (Koichi Itoh) Molecule-Based Magnetic Materials: Theory, Techniques, & Applications (Mark M Turnbull)

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)








Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Magnetization and magnetic susceptibility Molecules containing a unique magnetic center without first order orbital momentum “ Molecules containing a unique magnetic center with first order orbital momentum Low spin-high spin transition Intermediate-spin and spin admixed states Isotropic interaction in dinuclear compounds “ Dipolar, anisotropic and antisymmetric interactions in dinuclear compounds “ Trinuclear compounds and compounds of higher nuclearity “ Magnetic chain compounds “






Course Title Experimental methods in X-ray crystallography



on Laboratory



ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8

Semester Spring Course Language Turkish/English

Course Type

Basic Scientific


Social Elective

Course Objectives

To develop strong background for the experimental methods in X-ray crystallography


To learn experimental methods in X-ray crystallography To learn data collection techniques



ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)








Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Experimental methods in X-ray crystallography X-ray sources Conventional generators Data collection techniques for single crystals The single crystal diffractometer Area detectors Data collection techniques for polycrystalline materials X-ray diffraction of polycrystalline materials Diffractometers used for polycrystalline materials Uses of powder diffraction Data reduction Lorentz correction Polarization correction Relative scaling





Course Title Molecular nanomagnets Code : FFZ 5255 Institute: Science Field: Physics


on Laboratory



ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To develop strong background for the molecular nanomagnets


To learn Magnetic interaction in molecular systems To learn Single molecule magnets


Molecular Nanomagnets (Dante Gatteschi) Molecular magnetism ( Olivier Kahn) Molecular Magnetism: New Magnetic Materials (Koichi Itoh) Molecule-Based Magnetic Materials: Theory, Techniques, & Applications (Mark M Turnbull)

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)








Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Magnetic interaction in molecular systems The spin hamiltonian approach Single ion levels Exchange interaction Observartion of microscopic magnetism Magnetic techniques Specific heat measurement Single molecule magnets Rational design of SMMs Synthetic strategies to SMMs Cyanide based clusters Mn12 family Fe8 clusters Mn4 clusters

Instructors Assoc. Prof. Dr. Hülya KARA





Course Title: NUMERICAL APPLICATIONS FOR NUCLEAR EVENTS

Code : PHYS5259 Institute: THE INSTITUTE OF SCIENCE AND TECHNOLOGY Field: PHYSICS




ECTS

3 -- -- -- -- -- 3 3 8

Semester Spring Language Turkish

Course Type


Technical Elective

Social Elective

Course Objectives To learn the applications of Monte-Carlo method in nuclear physics


Learning Monte Carlo method


Monte Carlo Method for random walk problems E.D. CASHWELL & C.J. EVERETT Pergamon Press, 1959 Monte Carlo Methods J.M. HAMMERSLEY &D.C. HANDSCOMB London Chapman&Hall 1979. Monte Carlo Principles and Neutron Transport Problems J. SPANIER & E.M.GELBARD Add. Wes. Pub. Comp.1969. Monte Carlo Transport of Electrons and Photons T.M. JENKIS, W.R. NELSON & A. RINDI Plenum Press, 1988

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

The general of Monte Carlo Methods “ “ Statistical Terms Random Numbers “ “ Direct Simulation “ “ General Principles of the Monte Carlo Method “ “ Discrete and Continuous Random Walk Processes “ “ Physical Applications “ “ “ “

Instructor/s Prof.Dr. ASUMAN AYDIN


Website http://w3.balikesir.edu.tr/~aydina/


Course Title: Introduction to Computational Condensed Matter Physics II

Code : FFZ5260 Institute: Natural and Applied Sciences Field: Physics



T+A+L=Credit ECTS

16x3=48

Duration of lectures (16x3 total

of 48 lecture hours)

0 0 0 5x15=75

16x5=80 Out of class self-study (preperation, exercises)

2x15= 30 (Midterm)

1x20= 20 (Final exam)

253 3 8



Technical Elective

Social Elective

Course Objectives

The aim of the course is to introduce computational methods in condensed matter physics at the graduate level.


The student will gain the necessary tools to pursue his/her own research in computational condensed matter physics. Students should be able to calculate material properties from first principles.


Electronic Structure, Richard M. Martin, Cambridge University Press, 2004.

Atomic and Electronic Structure of Solids, Efthimios Kaxiras, Cambridge University Press, 2003.

Electronic Structure Calculations for Solids and Molecules, Jorge Kohanoff, Cambridge Univ. Press, 2006.

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1

2

3 4

5

6

7

8 9

10

11

12

13 14

Local density approximation (LDA)

Pseudopotential approximation

Norm-conserving pseudopotentials Semilocal pseudopotentials and fully separable Kleinman-Bylander form

Vanderbilt ultrasoft pseudopotentials

Projector augmented waves (PAW) method

Self-consistent solution of Kohn-Sham equations and density mixing schemes

The planewave expansion and iterative diagonalization methods Brillouin zone integration

Smearing methods

Beyond LDA : Generalized gradient approximation (GGA)

Beyond LDA : Self-interaction correction (SIC)

Beyond LDA : On-site Hubbard U repulsion (LDA+U) Beyond LDA : Exact HF exchange (EXX)





Course Title: Structure and evolution of stars Code : FFZ5261 Institute: THE INSTITUTE OF SCIENCE

AND TECHNOLOGY

Field: PHYS ICS




ECTS

3 3 3 8


Course Type


Technical Elective x

Social Elective

Course Objectives To obtain knowledge on structure and evolution of the stars


Learn ing the stellar structure and evolution


Books on the Stellar structure and evolution

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)



Homework Term Paper


x 40 Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction

Observational basis

Observational basis

Physical state of the stellar interior Physical state of the stellar interior

Physical state of the stellar interior

Nuclear reactions

Nuclear reactions

Nuclear reactions Mathematical techniques

Mathematical techniques

Mathematical techniques

Initial stellar structure

Evolution phases

Instructor/s Asist. Prof. Dr. Gülay İNLEK


Website

MASTER/PHD COURSE DEFINITION FORM

Course Title: Nonlinear Physics II Code : FFZ5262 Name of The program: PHYSICS

Education and Teaching Loads Credits

Theory Application

Laboratory Project/Field Study

Homework

Other Total Credit ECTS Credit

16x3= 48

0

0

-

5x15=75

16x5=80 1x15= 15 Midterm exam 1x20= 20 Final exam

238

5

8

Semester Spring Course Language Turkish

Kind of Course Fundamental Field Course

Field Course Technical Optional

Social Optional

Content of Course

Computation projects in the Non-linear physics, Identification of the numerical calculations, Generate random numbers in computer , Monte Carlo method, Ising Model, Aggregate models, Diffusion limited aggregation model, Aggregation models with deposition, Diffusion -deposition model, Diffusion -deposition model, Molecule dynamic and Data analyses and interpretation

Purpose Of the Course


Learning Output(s) and Efficiencies

To learn the computation projects in the Non-linear physics, To learn the calculation of the numerical problems, To learn the generate random numbers in computer, To learn the Monte Carlo methods, To learn the Ising model, To learn the aggregate model and applications, To learn the date analyses and interpolation.

Course Book and/or other Sources

[1] Tapmaz, Recep, Sayısal Çözümle, Literatür Yayıncılık, 2002, İstanbul. [2] Karagöz, İhsan, Sayısal Analiz ve Mühendislik Uygulamaları, UÜ Güçlendirme vakfı Yayını,2001,Bursa. [3] Lui Lam, Non-Linear physics for beginners, Word Scientific, 1998. [4] Bekir Karoğlu, “Sayısal Fizik”, Seyir yayınları, 2004, İstanbul.

EVALUATION CRITERION

Theoretic Course Project Course

to mark (X) Percentage

(%) to mark(X) Percentage (%)

Midterm Exam

X 30 Midterm Exam

Quiz X 5

Homeworks X 5

Semester homework (Project,report )

Oral Exam

Laboratory Final Exam


Other

Week Course Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Computation projects in the Non-linear physics Generate random numbers in computer Monte Carlo method I Monte Carlo method II Random walks Pattern formation Aggregate models Second order transitions I Second order transitions II Ising Model I Ising Model II Molecule dynamic Data analyses and interpretation I Data analyses and interpretation II

Course Teacher Assist. Prof. Dr. Mehmet BAYIRLI


Web Address



Course Title: ADVANCED RADIATION PHYSICS

Code:FFZ5263 Institute: SCIENCE AND TECHNOLOGY Field: PHYSICS



T+A+L=Credit ECTS

3 - - 3 8

Semester Autumn /Spring Language Turkish

Course Type


Technical Elective

Social Elective

Course Objectives

To learn the radiation physics with detailed


To learn the radiation physics


Nuclear Physics I. KAPLAN Addison-Wesley Company, 1962. Nuclear Radiation: Risks and Benefits E. Pochin, Oxford:Clarendon, 1983.

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Fundamental Concepts of Nuclear and Radiation Physics Radioactive Decay Radiation sources Ionizing and Non-ionizing Radiation Alpha, beta, gamma decays Interaction of Radiation with Matter Cross sections Charged particle interactions and energy loss mechanism Photon interactions and energy loss mechanisms Radiation measurement detector Radiation Protection Radiation-Dose Medical Applications of Radiation “ ”

Instructor/s Prof.Dr. ASUMAN AYDIN


Website http://w3.balikesir.edu.tr/~aydina/


Course Title: Particle Physics II

Code : FFZ5265




T+A+L=Credit ECTS

14x3=42 0 0 - 5x14=70 88 200 3 8

Semester Spring Language English

Course Type


Technical Elective

Social Elective

Course Objectives

To provide a framework for understanding the Particle Physics II and solve related problems in this course.


To gain the goals and contents given below: Quantum Electrodynamics (QED), The Dirac Equation, Electrodynamics of Quarks and Hadrons,

Quantum Chromodynamics (QCD), Weak Interactions, Gauge Theories


Introduction to Elementary Particles, David Griffiths, John Wiley & Sons, Inc.ISBN 0-471-60386-4

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Quantum Electrodynamics

The Dirac Equation Solutions to the Dirac Equation

The Feynman Rules for QED

Electrodynamics of Quarks and Hadrons

Electron-Quark Interactions, Elastic Electron - Proton Scattering

Inelastic Electron - Proton Scattering Quantum Chromodynamics (QCD), The Feynman Rules for QCD

Applications of QCD

Weak Interactions

Decay of the Muon, Decay of the Neutron, Decay of the Pion

Neutral Weak Interactions Gauge Theories

The Mass Term, Spontaneous Symmetry Breaking, The Higgs Mechanism

Instructor/s Prof.Dr.Levent SOLMAZ


Website


Course Title: Material Production And Characterization Techniques-II

Code: FFZ5266 Institute: Science Field: Physics




14x3= 42 0 0 - 14x6= 84 14x6=84 210 3 8


Course Type


Technical Elective

Social Elective

Course Objectives

To introduce special experimental methods and techniques about material production and characterization to greduate students who need to work experimentally.


1) To learn material designing and experimental techniques of material production 2) To understand spectroscopic methods which using for investigation of materials 3) To understand working principles of powder crystal and single crystal diffractometers 4) To understand structural, electrical, magnetic and optical properties of materials


Introduction to Solid State Physics (C. Kittel)

Modern Fiziğin Kavramlar ı (Arthur Beiser, Çev.: Gülsen Önengüt, Akademi yayıncılık, Ankara) Fundamentals of crystallography (C. Giacovazzo) Enstrümantal Analiz Yöntemleri (Prof.Dr. Atilla Yıldız, Prof.Dr. Ömer Genç, Prof.Dr. Sema Bektaş, Hacettepe Yayınları) Nanophysics and Nanotechnology (Edw ard L. Wolf, Wiley-VCH)

ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





X Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Applications of material producting and synthesis of single-crystal Applied Research Laboratory Study Spectroscopic methods for analysis of materials; UV-Visible, FTIR, X-ray spectroscopy, ” ” ” ” Powder Crystal X-ray diffractometer (XRD) Single crystal X-Ray Diffractometer Obtaining structural data by using spectroscopic methods Computer based structural analysis methods ” ” ” ” ” Structural and electrical properties of materials Magnetic and optical properties of materials Characterization of materials with the experimental data Applied Research Laboratory Study





Course Title: Characterization Techniques of Magnetic Structures

Code : FFZ5267




T+A+L=Credit

ECTS

14x3=42 0 0 5x14= 70

14x5=70 Exterior study hours (preliminary, review) 1x8=8 (Midterm) 1x10= 10 (Final examination

200 3 8


Course Type


Technical Elective

Social Elective

Course Objectives

To obtain knowledge on characterization techniques of magnetic structures


Learning the structural, magnetic and magneto resistance Characterization Techniques of magnetic structures


Books including the characterization techniques of magnetic structures

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction Electrochemical characterization techniques Electrochemical characterization techniques Structural characterization techniques X-ray diffraction Crystal structure analysis by X-ray diffraction Characterization of surface morphology Elemental analysis techniques Electrical conduction properties Magnetoresistance characterization Magnetoresistance system Magnetic characterization techniques Vibrating sample magnetometer (VSM) Magnetic characterization with vibrating sample magnetometer

Instructor/s Asist. Prof. Dr. Hilal KURU


Website


Course Title: Scattering Mechanisms in Semiconductors

Code :FFZ5268 Institute: Science Field: Physics



T+A+L=Credit ECTS

14x3=42 0 0 - 5x14= 70 14x5=70

200 3 6


Course Type


Technical Elective

Social Elective

Course Objectives

The defini tion of basic scattering mechanisms affecting the trans port properties of

semiconductors


To have knowledge on 2 and 3-dimensional scattering mechanisms


All books of semiconductors , lecture notes and articles

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Transport properties in semiconductors Hall effect and analysis Boltzmann Transport Equation Introduction to the scattering mechanisms in 2 and 3- dimensional structures Acoustic phonon scattering Optic phonon scattering Impurity scattering Dislocation scattering Alloy scattering Interface roughness scattering Investigation of the scattering mechanisms in 2-dimensional structures Investigation of the scattering mechanisms in 3-dimensional structures Exercise 1 Exercise 2

Instructor/s Prof. Dr. Sibel Gökden





Course Title: Radiation Dosimetry II

Code : FFZ5269




Field Study


16x3= 48 0 0 - 5x15=

75

16x5=80

(preliminary work)

1x15= 15 (Midterm)

1x20= 20 (Final)

238 3 8


Course Type


Technical Elective

Social Elective

Course Contents



resonance, Pulse spectrometers, Measurement techniques of relaxation times, NMR in solids, Dipol-Dipol

interaction, NMR in liquid

Course Objectives















ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Spectroscopy and Magnetic Resonance Basic principal of Magnetic Resonance

Magnetic Moment

Dynamic investigation of Spin System; Classical Method

Motion equations in Isolated spin system

Motion equations in unisolated spin system The energy absorbed by Spin System


Continues wave NMR

Pulse spectrometers

Measurement of relaxation times NMR in solids


NMR in liquids





Course Title: Electron Spin Resonance Spectroscopy II

Code : FFZ 5270 Name of the Programme: Physics



Field Study


16x3= 48 0 0 - 5x15=

75

16x5=80 (preliminary work)

1x15= 15

(Midterm)

1x20= 20 (Final)

238 3 8


Course Type

Basic Scientific


Social Elective

Course Contents



resonance, Pulse spectrometers, Measurement techniques of relaxation times, NMR in solids, Dipol-Dipol interaction, NMR in liquid

Course Objectives















ASSESSMENT CRITERIA


If any,

mark as (X)

Percent (%)

If any,

mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Spectroscopy and Magnetic Resonance

Basic principal of Magnetic Resonance

Magnetic Moment

Dynamic investigation of Spin System; Classical Method Motion equations in Isolated spin system

Motion equations in unisolated spin system

The energy absorbed by Spin System


Continues wave NMR Pulse spectrometers

Measurement of relaxation times

NMR in solids


NMR in liquids





Course Title: Applications of Density Functional Theory

Code : FFZ5271





ECTS

14x3=42 0 0 0 5x14=70 14x5=70

200 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

To learn the fundamental concepts of Density Functional Theory.


The students taking the course will have a basic knowledge of the fundamental concepts of Density Functional Theory.


1. R. G. Parr, W. Yang, “Density Fuctional Theory of Atoms and Molecules”Oxford University Press, New york, 1989. 2. R. M. Martin, “Electronic structure”, Cambridge University Press, Cambridge, 2004.

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction to Pseudopotentials, Orthogonolized plane waves (OPW) pseudopotentials Norm-conservative pseudopotentials (NCPPs) Ultrasoft pseudopotentials and PAW method Band structure calculation methods Band structures and density of states (DOS) Ab initio molecular dynamic Geometry optimization by ab initio and Density Functional Theory (DFT) Ab initio calculations by Plane waves and grid Ab initio calculations of elastic properties Basic formulation of lattice dynamics and density of states Calculation of vibrational frequency by DFT Small displacement method and phonon dispersion curves Ab initio calculations of optical properties Homework presentation



Website

X


Course Title: Structures and properties of solids II

Code : FFZ5272





ECTS

14x3=42 0 0 0 5x14=70 14x5=70

200 3 8


Course Type


Technical Elective

Social Elective

Course Objectives

To learn the fundamental concepts of Solid state physics .


The students taking the course will have a basic knowledge of the fundamental concepts of Solid state physics.


1. J.R.Hook, H.E.Hall, Solid State Physics'' 2. C. Kittel ''Introduction to Solid State Physics''

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Sound velocities Lattice vibrations of one dimensional crystal. Lattice vibrations of three dimensional crystal. Phonons and heat capacity arising from lattice vibrations Heat capacity: Classical approximation, Einstein and Debye models Anharmonic effects '' Thermal conductivity by phonons '' Semiconductors and types of semiconductors '' Optical properties of semiconductors and effective mass Application of free electron model to semiconductors ''



Website

X


Course Title: Electromagnetic theory II

Code : FFZ5273




T+A+L=Credit ECTS

14x3=42 0 0 0 5x14=70 14x5=70

200 3 8


Course Type


Technical Elective

Social Elective

Course Objectives

To learn the fundamental concepts of electrodynamics .


The students taking the course will have a basic knowledge of the fundamental concepts of electrodynamics.


J.D. Jackson, "Classical Electrodynamics", John & Sons, Inc., (1975).

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Plane waves in a nonconducting medium and conductors Linear and c ircular polarization of plane waves Poynting vector for monochromatic plane waves Reflection and Refraction of electromagnetic waves at a plane interface between dielectrics Polarization by reflection, total internal reflection, frequency dispersion characteristics of dielectrics, conductors, and plasmas Group velocity and Kramers-Kronig relations Cylindrical cavities and wave guides Resonant cavities, power losses in a cavity and Q multiplier Dielectric wave guides Electric dipole fields and radiation, magnetic dipole, electric quadrapole fields Scatering and diffraction '' Rölativistic electromagnetism ''



Website

X


Course Title : Synthesis and Characterization Techniques of Magnetic Nanoparticles

Code : FFZ5274





ECTS

3x14=42 5x14=70 5x14=70 200 3 8



Technical Elective

Social Elective

Course Objectives

Teaching the synthesis techniques of magnetic nanoparticles

Teaching the characterization techniques of magnetic nanoparticles


4) Recognizing the magnetic nanoparticles and their properties

5) Learning the techniques to synthesize the magnetic nanoparticles

6) Learning the techniques to characterize the magnetic nanoparticles


13) Jiles D., Introduction to Magnetism and Magnetic Materials, Chapman & Hall, London (1996)

14) Cullity B.D., Introduction to Magnetic Materials, Consulting Editor: Cohen M., Addison -Wesley

Publishin g Company, Massachusetts (1972)

15) Klabunde K. J., Nanoscale Materials in Chemistry, John Wiley & Sons, Inc.,New York, (2001)





18) Cullity B.D., Stock S.R. Elements of X-Ray Diffraction (Third Edition),Pearson Prentice Hall, New

Jersey (2001)

19) Douglas A. Skoog, F. James Holler, T imothy A. Nieman, Principles of Instrumental Analysis,

Çevirenler: Kılıç E., Köseoglu F., Yılmaz H., Fifth Edition Saunders College Publishing, Florida (1998)

ASSESSMENT CRITERIA


If any, mark as

(X) Percent (%)

If any, mark as (X)

Percent (%)




Term Paper, Project Reports, etc. X %20 Oral Examination



Other

Week Subjects

1 2

3 4 5 6

7 8 9 10

11 12 13

14

Introduction Magnetic nanoparticles, structural and magnetic properties, application areas

Electrochemical techniques Vapor phase synthesis tecniques Ball milling Sol-gel

Co-precipitation Hydrothermal synthesis Thermal decomposition Microemulsion

X-ray diffraction (XRD) Fourier transform infrared spectroscopy (FTIR) Transmission electron microscope (TEM)

Vibrating sample magnetometer (VSM)



Website


Course Title: Preparation Techniques of Biosensors

Code : FFZ5275




T+A+L=Credit ECTS

42 - - - - 42 3 8


Course Type

Basic Scientific


Social Elective

Course Objectives

The course focuses on the typical aspects of biosensors and its instrumentation. The student should be able to define biosensors as analytical devices incorporating a biological material (eg. tissue, microorganisms, organelles, cell receptors, enzymes, antibodies, nucleic acids etc), a biologically derived material intimately associated with, integrated within a physiochemical transducer, or transducing microsystem, which may be optical, electrochemical, thermometric, piezoelectric or

magnetic.


In the biosensor preparation techniques course, the students should be able to define

biosensors as devices incorporating a material integrated within a physicochemical transducer, or transducing microsystem, which may be optical, electrochemical,

thermometric, piezoelectric or magnetic. In addition the students will learn where and which purposes the biosensors can be used.


Enzyme and Microbial Biosensors”, Humana Press Inclined, (1998) A. Telefoncu (Ed.), “Biyosensorler”, Ege Universitesi, (1999) T. M.Canh,”Biosensors” Chapman and Hall, (1993)

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





- Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Biosensors, Basic components of biosensors, Characteristics of biosensors, To be considered in the preparation of biosensor properties Preparation of the biosensor, Converter types and properties in biosensors, Traditional Transducers, Piezoelectric Transducers, Conductive Transducers, Electrical Capacitance Transducers, Thermometric Transducers, FET Type Transducers, Optimization of biosensor , Characterization of biosensor.



Website


Course Title: Technology of Biosensor Code : FFZ5276





ECTS

42 - - - - 42 3 8


Course Type


Technical Elective

Social Elective

Course Objectives

In thir lesson, Biosensors will have detailed information about the recently held biosensors with technology.


Biosensors and features, learn the latest developments in the field of application of biosensors and biosensor technology.


A. Telefoncu (Ed.), “Biyosensorler”, Ege Universitesi, (1999) T. M.Canh,”Biosensors” Chapman and Hall, (1993)

ASSESSMENT CRITERIA


If any,

mark as (X) Percent

(%)

If any, mark as (X)

Percent (%)





- Oral Examination



Other

Week Subjects

1 2 3 4 5 6 7 8 9 10 11 12 13 14

Introduction to biosensors, Biotechnological approaches in biosensors, The structure and working principle of biosensors, Use of biosensors purposes, Applications of biosensors, The use of biosensors in food analysis The use of biosensors in food control The use of biosensors in environmental analysis Medical use of the biosensor, Medical use of the biosensor, The use of biosensors in the defense field, Recent advances in biosensor applications Approaches in the development of biosensors, The use of biosensors and importance.



Website


Course Title : Applications of Functional Magnetic Nanoparticles

Code : FFZ5277





ECTS

3x14=42 5x14=70 5x14=70 200 3 8



Technical Elective

Social Elective

Course Objectives

Teaching the application areas of functional magnetic nanoparticles


7) Recognizing the use of functional magnetic nanoparticles in applications








24) J.P. Jolivet, “Metal oxide chemistry and synthesis, From solution to solid state”, John Wiley & Sons,

Inc.,London, (2003)

25) Vicki H. Grassian (Editor), “Nanoscience and Nanotechnology, Enviromental and Health Impacts”, John

Wiley & Sons, Inc., New Jersey, (2008)

ASSESSMENT CRITERIA


If any, mark as

(X) Percent (%)

If any, mark as (X)

Percent (%)





X %20 Oral Examination



Other

Week Subjects

1 2

3 4 5 6

7 8 9 10

11 12 13 14

Introduction Synthesis techniques of magnetic nanoparticles for the applications

Synthesis techniques of coated magnetic nanoparticles for the applications Applications in diagnosis and therapy in medicine Applications in magnetic resonance imaging Applications in drug delivery

Applications in drug delivery Applications in biosensors Applications in immobilization Applications in immobilization

Magnetic hyperthermia system Applications in magnetic hyperthermia Applications in magnetic hyperthermia Applications in electronic and recording technology



Website

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