Course Name

Advanced Solid State Chemistry

Summary

Lecture Objectives

• Solid State Chemistry focuses on the chemical properties and structures of solid materials. This course covers topics such as crystal structures, crystal defects, and solid-state reactions. Key concepts include bonding theories, electronic structure, and band theory. Students will study the physical properties and applications of metals, semiconductors, and insulators. Experiments are conducted to learn methods for analyzing crystal structures and measuring the properties of solid materials. The course has applications in materials science, electronics, and physics. Students will learn techniques for the synthesis and analysis of solid materials. Understanding the mechanisms and kinetics of chemical reactions in the solid state is a primary goal. This course provides a foundation for advanced studies in chemistry and materials science.

Course Name

Advanced Physical Chemistry

Summary

Lecture Objectives

• This course introduces not only the basic theory of analytical chemistry and physical chemistry, but also the principles of analytical methods used in modern chemistry, and teach the principles and background theories of various advanced analytical methods essential for thesis research. In particular, this course is designed to learn highly sensitive analysis technology for radioactive and non-radioactive materials using lasers, mass spectrometers, and sensors.

Course Name

High-level Radioactive Waste Disposal Technology

Summary

Lecture Objectives

• This course covers geologic characteristics, disposal technologies, international practices, and related theories for the safe disposal of high-level waste with high thermal and radioactive levels.

Course Name

Radioanalytical Chemistry

Summary

Lecture Objectives

• 방사성물질에 대한 핵종별 분리기술를 이해하고 기기분석 및 정량분석에 대한 원리를 이해하고 그 응용에 대해 알아본다.

Course Name

Radiochemistry and Nuclear Chemistry

Summary

Lecture Objectives

• This course is designed to understand the basic theories of radiochemistry, such as the physical properties and chemical behaviors of radioactive materials and learn radiochemistry by teaching on the handling and application of radioactive nuclides. Several subjects such as radioactive decay, nuclear reaction, radioactive isotopes, interaction of radiation with matters, detection and measurement of radioactivity, radioanalysis and tracers, nuclear fuel cycle, radionuclides in the geosphere and the biosphere will be covered in this lecture.

Course Name

Special Topics in Radiochemistry

Summary

Lecture Objectives

• Special Topics in Radiochemistry is designed to understand the latest trends related to the radiochemistry and nuclear industry and its understanding and discussions are conducted. Lecture is dealing with various topics such as actinide chemistry, radiation science, nuclear fuel cycle, nuclear forensics, and decontamination.

Course Name

Introduction of Advanced Nuclear System Engineering

Summary

Lecture Objectives

• ● 신형 원자로 종류, 특성, 원리 이해를 위한 기초 물리 ● 각종 원자로 구현을 위한 설계 및 공학 핵심기술

Course Name

Introduction to Nuclear Reactor Safety Analysis

Summary

Lecture Objectives

• This course deals with the overall safety evaluation methodology for nuclear reactors including the thermal hydraulic safety analysis, the probalistic safety analysis, and the severe accident analysis methods.

Course Name

Nuclear Decontamination and Radioactive Waste Treatment

Summary

Lecture Objectives

• This course covers theories related to technologies for removing or reducing radioactive contaminants in and around nuclear power plants and restoring the environment of nuclear power plant sites before and after decommissioning. In addition, this course provides in-depth study of solid-state manufacturing technologies for safe storage of radioactive waste generated by nuclear power plants and nuclear facilities, and processing technologies for recycling spent fuel.

Course Name

Introduction to Nuclear Fuel Cycles and Nuclear Nonproliferation Technology

Summary

Lecture Objectives

• This course provides students not only the concepts and basics of nuclear fuel cycle but also the front-end (mining, refining, conversion and processing) and back-end nuclear fuel cycle (spent fuel transport, storage, dry/wet processing, radioactive waste classification and disposal). This course also explores the development status and history of the nuclear system and the nuclear fuel cycle, and acquires an overall knowledge of both aspects and sensitivity to the peaceful use of nuclear energy system. Students learn the nuclear non-proliferation technology of the nuclear fuel cycle, and study techniques for comprehensive analysis of nuclear fuel cycle alternatives using various proliferation resistance evaluation methodologies and policy-making methodologies, and application cases to future nuclear systems.

Course Name

Nuclear Chemical Engineering

Summary

Lecture Objectives

• This course aims to appli it to practical research by providing basic knowledge of chemical engineering needed to help students understand nuclear fuel cycle technologies, thereby enhancing their ability to understand and analyze chemical reaction systems applied in the field of nuclear fuel cycle. This course gives lectures on areas of mass and energy balance, equilibrium, reaction engineering, transport phenomena, and separation/purification to provide basic skills prior to in-depth research especially for students new to chemical engineering.

Course Name

Environmental Radioactivity Analysis

Summary

Lecture Objectives

• Provides a basic understanding of environmental radioactivity analysis containing sample pretreatment, chemical separation and measurement. Includes laboratory experiment and hands-on practice to determine environmental radioactivity