Curriculum
| Summary | English |
|---|---|
| special topics in industial chemistry | |
| Topics in the latest advanced fields of research in industrial chemistry. | |
| Inorganic Membranes | |
| The inorganic membrane is a discipline that combines chemical engineering and material engineering, and is being applied to new separation processes and chemical reaction systems. This lecture aims to understand the diffusion and mass transfer basics that are the basis of separation membranes, synthesis of various kinds of inorganic membranes, and characterization. | |
| Molecular Biotechnology | |
| Understand the basic concepts and principles of molecular biology such as DNA structure and properties, DNA replication, mRNA transcription and regulation, protein translation and regulation, and lecture on principles of gene recombination technology and industrial applications. | |
| Advanced Chemical Engineering Thermodynamics | |
| Reversible and irreversible theories and thermodynamic interpretation of chemical processes. Development and design of peripheral devices. | |
| Process Optimization | |
| Structure and analysis of systems, economic design standards, optimal design methods, and application of theories. | |
| Science3 and Technology of Nanoscale Materials | |
| This lecture lectures on scientific knowledge and technical methods on synthesis, manufacture, process and application of nanostructures and nanomaterials. | |
| Functional Polymer | |
| This course deals with the structure and properties of polymer materials used in cutting-edge industries and their applications. | |
| Advanced Electrochemistry | |
| This lecture focuses on the electrochemical theory, analysis and application techniques required to understand energy storage and conversion electrochemical processes. In particular, this course deals with the understanding of reaction principles of electrochemical based technologies such as batteries, fuel cells, and solar cells, and the characteristics of related materials. | |
| Nano Microsystem | |
| This course covers the basic principles and applications of microfluidic and chemical processes using lab-on-a-chip and process-on-a-chip fabrication techniques based on Microfluidic technology and nanometer and micrometer scale devices. | |
| Crystallization Technology | |
| This course teaches principles and application techniques of crystallization techniques such as crystal formation and growth, crystal structure, crystal size and distribution analysis. | |
| Interfacial Phenomena | |
| The mathematical expressions of thermodynamics and mass transfer at interfaces and the theory of suspension systems. | |
| Cellular Bioprocess Engineering | |
| In this lecture, cell structure and function of microorganisms, plants and animals, bioenergy theory, cell metabolism, metabolism engineering, industrial strain development, bioreactor and fermentation process, animal cell culture engineering, separation purification process are taught. Lectures on biotechnology industrial production such as protein drugs and functional biomaterials using microorganisms, plant and animal cells. | |
| Nucleic Acid Engineering | |
| Introduction to DNA / RNA / Protein chemical structure and synthesis, Biomolecule transformation methods, DNA / RNA / Protein analysis, Biomedical gene applications | |
| Advanced Polymer Chemistry | |
| The production method and physical properties of polymer materials. | |
| Sol-Gel Process | |
| This is a dual-level course for both seniors and graduate students who are interested in techniques for advanced materials preparation. Sol-gel process refers to room temperature formation of solid inorganic materials from molecular precursors in liquid solution. The goal of this course is to present the fundamental physical and chemical principles of the sol-gel process. | |
| Advanced Heat Transfer | |
| The heat transfer state between steady state and abnormal state is considered and presented as a mathematical model. | |
| High-tech Industry and Chemical Engineering | |
| Topics in the latest advanced fields of research in chemical engineering. | |
| Advanced Chemical Engineering | |
| Topics in recent advanced fields of research in chemical engineering. | |
| Research Applications of Instrumental Analysis | |
| We will study the theory, experimental method, and interpretation method of experimental results through experiments, presentations and discussions in detail. | |
| Advanced Mass Transfer | |
| The absorption, adsorption, separation and accompanying heat and mass transfer between gases, liquids and solid phases are discussed. | |
| Advanced Biochemical Engineering | |
| The course will cover the production of useful materials in the fields of pharmaceuticals, chemical industry and energy using microorganisms, plant and animal cell cultures, and genetic engineering, bioreactor engineering, and bioseparation processes. | |
| Advanced Transport Phenomena | |
| The mathematical expressions of thermodynamics and mass transfer at interfaces and the theory of suspension systems are covered. | |
| Industrial Biotechnology | |
| Understand important concepts and principles of microbial cell structure and function, microbial culture, microbial molecular biotechnology, industrial microbial and enzymatic engineering, and lecture on industrial application of industrial biotechnology. | |
| Colloid physics | |
| Understanding van der Waals force and its meaning from a macro perspective, Understanding electrostatic repulsion and electrokinetic phenomena by electric double layer, Understanding of colloid stability, Understanding of interactions between colloid particles at fluid interface, And current research trends. | |
| Advanced Bioengineering | |
| Understand the phenomena, structures, and constituent materials of living organisms and learn the engineering knowledge necessary to develop new substitutes and devices that can replace human functions and materials. | |
| Nano Convergence Materials and Chemistry | |
| This course is to acquaint students with understanding and application of fusion materials using innovative properties of nanomaterials and learning basic knowledge about nanofusion materials and chemical engineering approaches and applications. In addition, students will learn about nanocomposites, nanostructures, nanopatterning, nanocomposites, chemical synthesis methods for biofusion, process and physical manufacturing equipment, and functionalization technologies. | |
| Advanced Organic Chemistry | |
| Substitution reactions and elimination reactions of aliphatic compounds and reactions on carbonyl and benzene derivatives are discussed, and the reactivity and substituent effect according to the structure will be discussed. We will also discuss organic synthesis using these reactions. | |
| Advanced Fluid Mechanics | |
| his course extends the basic principles of fluid mechanics not only in large-scale chemical process systems, but also in gas and liquid flow phenomena in living systems such as the human body. Understand the basic principles and equations of fluid flow in various types of boundary conditions. | |
| Advanced Energy Engineering | |
| Consider future energy that could replace existing energy. | |
| Organic Electronic Materials | |
| This lecture will explore “organic electronic materials” considering next generation electronic material. The organic electronic materials are a promising material for wearable and implantable electronics due to its high flexibility and biocompatibility. Thus, the students will learn about history, design, property and even applications of organic electronic materials. | |
| Advanced Metabolic Engineering | |
| The first goal of this course is to understand the intrinsic metabolism in the cells. Based on this understanding the final goal is to modify the pathway of the cells for an increased production of useful metabolites or production of novel metabolites. For this purpose relevant molecular biological skills of modifying and inventing metabolic pathways will be discussed. | |
| Advanced Biomaterials | |
| Next Generation Sequence Analysis Technology and SNP Measurement Method Developed After Genome Project, and Protein and Cell Analysis Technology Using Nanobiotechnology. | |
| Polymer Materials | |
| The materials used in the polymer industry are introduced and their characteristics are discussed. | |
| Advanced Process Control | |
| This course deals with the control mechanism of chemical process control and the optimum control relation of reaction system, and discusses the characteristics of control system and the analysis of abnormal condition. | |
| Nanomaterials and its Process | |
| Synthesis and characterization of various types of nanomaterials, process and application using them, and characteristics of various nano processes will be discussed. | |
| Membrane Separation Technology | |
| The basic concepts of definition, classification and structure of membranes, membrane fabrication, permeation theory and membrane module process are covered. | |
| Advanced Ceramic Engineering | |
| Material and chemical properties, structure and classification of ceramics will be studied and applications. | |
| Advanced Industrial Electric-chemistry | |
| This course is designed to teach technological aspects of hi-tech industry such as IT, BT, and NT. Applications of IT, BT, and NT to space and robotics technologies are also covered. | |
| Numerical Analysis in Chemical Engineering | |
| This course deals with the application of numerical analysis for the computerization of a model using a normal room and a normal room which are frequently used in a chemical system. | |
| Advanced Chemical Engineering Mathematics | |
| This course deals with finding solutions to chemical engineering problems using linear normal and partial differential equations, vectors, and Laplace transformations. | |
| Functional Inorganic Nanostructured Materials | |
| The objective of this course is to learn the technical skills of the characteristics, synthesis, analysis, and application of various kinds of inorganic nanomaterials, and to learn the methodologies that can be used in the actual industrial field through the engineering approach to its use. | |
| Introduction to materials science and chemical engineering | |
| In this class, the principles and applications in materials science for chemical engineering will be lectured. During the class, the atomic/molecular bondings with material structures and properties such as mechanical, electrical, and properties will be lectured. Also, recently research results will be introduced and discussed to design advanced materials for chemical engineering. | |
| Interface Engineering & Applications | |
| 현상 등과 관련된 이론강의 및 관련 최신 연구동향 분석 및 응용을 학습한다. This class is a theoretical lecture related to physical/chemical phenomena at the interface of two or more phases, such as gas-liquid, liquid-liquid, liquid-liquid, solid-gas, solid-liquid, solid-solid, etc. In addition, To learn analyze and application of the latest research trends will be lectured. | |
| Advanced Display Process | |
| This course is designed to conduct industry-university collaborative project about display part(Flexible Display, OLED, PeOLED, QLED, etc.) | |
| Hybrid Materials Project | |
| This course is designed to conduct industry-university collaborative project about new material manufacturing process and property control process. |