For more details on the courses, please refer to the Course Catalog
| Code | Course Title | Credit | Learning Time | Division | Degree | Grade | Note | Language | Availability |
|---|---|---|---|---|---|---|---|---|---|
| PHY7001 | Classical Mechanics | 3 | 6 | Major | Bachelor/Master/Doctor | Physics | English | Yes | |
| This lesson considers the advanced course of Newtonian mechanics which describes the macroscopic objects. Main subjects are Newton's laws, dynamics of Lagrangian and Hamiltonian, Accelerated coordinate systems, scattering, rigid bodies, oscillations, perturbation theory and the classical field theory. | |||||||||
| PHY7002 | Quantum Mechanics | 3 | 6 | Major | Bachelor/Master/Doctor | Physics | English | Yes | |
| This subject studies mathematical introduction, the postulates, simple problems in one dimension, the classical limit, the harmonic oscillator, the Heisenberg uncertainty principle, rotational invariance and angular momentum, the hydrogen atom, spin, the addition of angular momenta. | |||||||||
| PHY7003 | Electromagnetism | 3 | 6 | Major | Bachelor/Master/Doctor | Physics | English | Yes | |
| In electromagnetism 1, students learn mainly about static electromagnetism, which contains basics of electrostatics, electrostatics with boundary conditions, electrostatic in matters, basics of magnetostatics, magnetostatics with boundary conditions, magnetostatics in matters, and Maxwell's equations. | |||||||||
| PHY7004 | Statistical Mechanics | 3 | 6 | Major | Bachelor/Master/Doctor | Physics | English | Yes | |
| Statistical mechanics deals thermodynamics and statistical physics at the level of graduate course. This lesson considers the following subjects: the laws of thermodynamics, transport phenomena, classical statistical mechanics, canonical ensemble, quantum statistical mechanics, fermion systems, boson systems, superfluidity, the Ising model, and phase transition. | |||||||||
| PHY7005 | Special Topics in Physics Ⅰ | 3 | 6 | Major | Bachelor/Master/Doctor |
3-4
1-4 |
Physics | Korean | Yes |
| Topics selected in newly developed physical theories and experiments. | |||||||||
| PHY7006 | Special Topics in Physics Ⅱ | 3 | 6 | Major | Bachelor/Master/Doctor |
3-4
1-4 |
Physics | - | No |
| Topics selected in newly developed physical theories and experiments. | |||||||||
| PHY7007 | Frontiers in Physics | 3 | 6 | Major | Bachelor/Master/Doctor |
3-4
1-4 |
Physics | - | No |
| New Science and Technology have been developed in a tremendously rapid speed, and several fields are opened in a revolutionary fashion. All the contents of the modern physics cannot be taught in a one-semester course. General, basic materials are taught in "Modern Physics" course, and detailed developments are dealt with in this "Frontier Topics in Physics" course. | |||||||||
| PHY7008 | Surface Physics | 3 | 6 | Major | Bachelor/Master/Doctor |
3-4
1-4 |
Physics | - | No |
| These days, new materials/structures continuously emerge and novel devices based on these materials/structures have extensively developed alongside the innovative advances in science and technology. Therefore, there is a growing importance of studies that understand the physical properties of the materials/structures and characterize the device performances based on the functionality of the materials/structures. In this course, we will draw attention to the relationship between the materials/structures and physical phenomena and learn to analyze those from a physical perspective. In addition, we will study the operational mechanism of the analytical instruments which will aid strongly in understanding various materials/structures and the functional device properties. Having the fundamental knowledge of Quantum Mechanics, Electromagnetism and Solid State Physics will be of use to comprehending this course. The course provides: 1) Understanding the crystal structures, especially, the concept of surface and interface of materials/structures, 2) the principle of each analysis instrument to characterize the electrical, optical, magnetic, thermal, mechanical properties. 3) Principles and analytical techniques such as electron microscopes, atom force microscopes, X-ray diffraction, etc., and 4) spectroscopic methods for characterizing the electronic structures and the chemical property of materials/structures will be explored as well. | |||||||||
| PHY7011 | Advanced Physics Experimental Design and Analysis | 3 | 6 | Major | Bachelor/Master/Doctor | 3-4 | Physics | - | No |
| This course is planned for those interested in the design, conduct, and analysis of advaned experiments in physical science. The course will examine how to design experiments, carry them out, and analyze the data they yield. Various designs are discussed and their respective differences, advantages, and disadvantages are noted. This course also provides the capstone experience to the core courses, bringing the knowledge gained in different courses together and making the connection between theoretical knowledge and the experimental foundations of this knowledge. Activities outside the classroom, such as independent research or study, allow students to further develop their knowledge and understanding. | |||||||||
| PHY7012 | Physics in Regional High-tech Industries | 3 | 6 | Major | Bachelor/Master/Doctor | Physics | - | No | |
| The importance of industry-university cooperation, such as cultivating human resources, technological innovation, and improving productivity through collaboration, is emerging in the trend of rapid social change, such as the full-scale of the fourth industrial revolution. The aim of this course is to provide a convergence curriculum in which high-tech industrial, academic, and research workers in Gyeonggi-do province participate jointly with the goal of fostering creative talents. | |||||||||
| PHY7018 | Genome physics | 3 | 6 | Major | Bachelor/Master/Doctor | Physics | - | No | |
| According to the central dogma of molecular biology, genome—the blueprint of life—is a collection of massive sequential information written in DNA that transcribes and translates into physical molecules such as RNA and proteins. Furthermore, the information-carrying genome itself is a meters-long physical polymer that utilizes the physics of folding and phase separation as a way of controlling the activity of information. Thus, studies of the interplay between information and physics is an essential subject in biophysics. In this course, we will learn how to interpret the central dogma from two different perspectives: information- and physics-based perspectives. The topics include sequence alignments of genomic and proteomic data, entropy in bioinformatics, analysis methods in genomics and proteomics, polymer physics of the genome, analysis methods in genomic structures. | |||||||||
| PHY7019 | Advanced Nanoelectronics | 3 | 6 | Major | Bachelor/Master/Doctor | Physics | - | No | |
| This lecture is to provide an introduction to fundamental concepts of nanoelectronics, including single electron effects and electron transport in nanoscopic systems, for physicists and applied scientists who are particularly interested in advanced electronic and semiconductor devices. Of paramount importance is the idea of understanding quantum dots, quantum wires, and quantum wells, and nanoelectronic applications of these structures. In particular, attention is focused on the quantization of electrical properties, such as conductance quantization and ballistic transport in low-dimensional systems, quantum interference effects arising from the wave nature of electrons, and tunneling phenomena in nanoelectronic devices. | |||||||||