Our department offers in-depth basic lectures and lectures
in a wide range of majors to deepen physical understanding.
Our department provides in-depth lectures on essential courses, and also provides a variety of detailed majors and experimental courses to provide classes related to students' research. In addition, seminar lectures and special research lectures are provided to review the latest research trends in each field.
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교과목명 | 학정번호 | 교과내용 |
---|---|---|
Mathematical Physics(1), (2) | PHY5101,5102 | We will discuss the basic mathematical tools need to understand nature. The contents will be useful tools to approach problems in physics and natural sciences. |
Electromagnetism | PHY6030 | - Apply the Maxwell equations to various phenomena, including optics of plane waves, radiation, scattering and diffraction - Formulate classical electrodynamics in the framework of special relativistic theory; obtain EM-unified and covariant desciption of electrodynamics - Learn various phenomena of relativistic radiation |
Mechanics | PHY6010 | The main goals of this course are: - To teach the principles and applications of the classical mechanics in the formalism of Lagrangian and Hamiltonian methods - To provide a thorough training in classical physics as a bridge for transitions onto modern physics - To provide a natural framework to introduce and practice various mathematical concepts in physics |
Quantum Mechanics | PHY6050 | Develop understanding of modern concepts of quantum mechanics: - Symmetry. - Approximation methods - Scattering - Path integrals -Radiation, Relativistic QM - Identical Particles |
Statistical Mechanics | PHY6060 | We aim to understand the modern concept of statistical physics. Basic laws of thermodynamics, Boson and fermions, Mean field approximation, Ginzburg-Landau theory, Critical phenomena, Linear response theory, and Quantum Brownian motion using Caldeira-Leggett method. |
Physics Lab | PHY6070, PHY6080 | This course will cover general electronics as well as the basics for computers needed for modern day experimental physics. |
Solid-state Physics | PHY6090 | Solid state physics is the study of condensed matters by utilizing comprehensive knowledge of many areas of physics such as crystallography, statistical mechanics, quantum mechanics, and electromagnetism. The primary goal of this course is to understand how the large-scale emergent properties of solid materials result from their atomic-scale periodic arrangements. |
Quantum Gravitation Theory | PHY8040-01 | This will be the first semester mainly covering the background material toward the study on the AdS/CFT correspondence. - some basics of gauge theory, general relativity. - basics of supersymmetry and supergravity - black holes - string theory, D-branes -AdS/CFT correspondence In the next semester, we will cover the application of AdS/CFT correspondence in the course: `String Theory` |
PRINCIPLES AND APPLICATIONS OF OPTICAL SPECTROSCOPY | PHY6150 | Principles of Optical Spectroscopy including Terahertz Time-Domain Spectroscopy (THz-TDS), Fourier-Transform Infrared Spectroscopy (FTIR), Spectrosellipsometry (SE), and Grating Spectrophotometry (GSP) with Applications |
NUCLEAR MATTER AT EXTREME CONDITON II | PHY8140-01 | Introduction to the physics of heavy ion collisions and the Quark-Gluon Plasma (QGP) in which quarks and gluons are deconfined from hadrons to move freely overthe volume much bigger than hardon. Extensive survey of the present status of both theory and experiment of QGP. |
PHYSICS OF NOVEL MATERIALS | PHY8240-01 | To study interesting materials that have been investigated in solid state physics. |
DEVICE PROCESSES AND MEASUREMENT PHYSICS | PHY8410-01 | The subject serves ion scattering theory and its application for physics and elctrical engineering students. |
Optical Properties of Materials | PHY8440-01 | Electromagnetism (EM) is one of the fundamental interactions in Nature. In this course, we will study the basic principles of EM and learn how to formulate the phenomena under a unified framework of Maxwell`s equations. Any necessary mathematical tools will be also studied during the course. |
Students in the integrated/PhD course must pass the PhD qualification to graduate. The Doctoral Qualification Examination is conducted twice a year and consists of four subjects: classical mechanics/electromagnetics/quantum mechanics/statistics. If the average credit for the subject is A0 or higher, the subject is exempted. This is a test to evaluate basic knowledge and understanding in the field of physics.