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1 | □ Curriculum for 2022-2023 | |||||||||||||||||||||||||
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3 | No. | Sub major | course | Subject title | point | Specification | ||||||||||||||||||||
4 | 1 | Green Chemical Engineering | master, doctor | Sustainable Green Chemistry and Engineering | 3 | This 'Sustainable Green Chemistry and Engineering' lecture is based on the concept of green chemistry to understand the synthesis of eco-friendly polymers and molecular design. Students acquire in-depth knowledge about the flow of the chemistry field after the climate agreement system through application examples of Korea. | ||||||||||||||||||||
5 | 2 | Green Chemical Engineering | master, doctor | Special Topics on Carbon Materials | 3 | This lecture specifically aims to provide a general introduction to six representative carbon materials (graphite, carbon fiber, carbon black, carbon nanotube, activated carbon, graphene). The lecture overviews the chemical/mechanical properties of these carbon materials and provides recent understanding of the manufacturing processes. Also, the goal of this lecture is to cultivate talented individuals with practical job competencies and expertise in carbon materials. | ||||||||||||||||||||
6 | 3 | Green Chemical Engineering | master, doctor | Computational Catalysis | 3 | To understand atomic reaction engineering and design heterogeneous catalysts, we study theory of electronic structure calculations and micro-kinetics and practice those. | ||||||||||||||||||||
7 | 4 | Green Chemical Engineering | master, doctor | Sustainable Polymers: Synthesis and Characterization | 3 | This study includes the introduction, polymerization method and mechanism, characteristics, industrial applications of bio-based or sustainable polymers. | ||||||||||||||||||||
8 | 5 | Green Chemical Engineering | master, doctor | Bio-based Specialty Chemicals | 3 | This lecture entitled “Bio-based Specialty Chemicals” covers follows: 1. Beginning with an introduction to the basics of sustainable feedback, biomass-based surfactants, cosmetics, coatings, adhesives, sealants, dyes/pigments, plasticizers, reinforcing agents, and nucleating agents; and acquire expertise in research trends and industrial applications of each fine chemical product. 2. The value chain of the industrial biochemical technology field through an introduction and in-depth study of each element technology of the chain (biomass pretreatment-biological/chemical conversion-bioplastics). | ||||||||||||||||||||
9 | 6 | Green Chemical Engineering | master, doctor | Catalytic Chemistry | 3 | This lecture provides an introduction to zeolites and various catalyst synthesis methods, catalytic surface reactions, catalytic reaction kinetics and energy industry applications for the cultivation of basic and major knowledge of catalysts, which are key materials in the chemical, environmental and energy industries. In particular, various catalytic reactions applied to chemical reactions are introduced through examples. | ||||||||||||||||||||
10 | 7 | Green Chemical Engineering | master, doctor | Advanced Chemistry for Catalysis | 3 | The purpose of this study is to cultivate key knowledge of the latest trends in catalysts, a key material in the chemical, environmental and energy industries. The first half aims to acquire knowledge and understanding of heterogeneous catalyst materials/ characteristic analysis/reaction theory/applications, etc. The second half of the year aims to introduce the basic principles of electrochemistry, a key research on the storage and conversion of renewable energy, and to understand and acquire electrochemical catalyst application technologies. | ||||||||||||||||||||
11 | 8 | Green Chemical Engineering | master, doctor | Chemical Reaction Engineering and Reactor Design | 3 | Chemical reactions are ubiquitous in nature and numerous chemical systems ranging from the smallest living organism to a large chemical plant. The chemical reactor is the essential element in most chemical industries. In many commercial operations of chemical processes, separation costs dominate, but the reactor determines the separation costs. This poses a strong motivation for chemical engineers to practice kinetic analysis and reactor design subject to costs and efficiencies. In this course, students will learn fundamental concepts and in-depth engineering skills regarding kinetics, mathematical descriptions for chemical reactions, engineering issues appearing in most chemical reactor operations, and finally design rules for classical and complex chemical reactors. | ||||||||||||||||||||
12 | 9 | Green Chemical Engineering | master, doctor | Introduction to Adsorption Process | 3 | Special Discussion of Adsorption Processes lectures on chemical engineering such as adsorption energy, adsorption rate and specific surface area of adsorbent, pore size distribution, and surface chemical state when adsorbent is adsorbed to the adsorbent. Also, it lectures on the understanding of inorganic chemical materials, synthesis of chemical engineering, and its application. In the application field, there lectures on the energy field (lithium secondary battery and capacitor) and environment field (harmful gas adsorption and purification of water pollution). | ||||||||||||||||||||
13 | 10 | Green Chemical Engineering | master, doctor | Chemistry for Polymer Surfaces and Interfaces | 3 | The improved understanding of polymer surfaces and interfaces has played important role to design the more advanced industrial items. This lecture will cover the basic theories related with polymer surfaces/interfaces phenomenons and wide ranges of their applied technologies further. | ||||||||||||||||||||
14 | 11 | Green Chemical Engineering | master, doctor | Nanomaterials & Fabrication | 3 | Recently, a lot of considerations on the synthesis and structure properties and application methods of new materials have emerged. In particular this lecture is about understanding the physical and chemical properties of materials that are expressed on the nanoscale, and how to synthesize and apply them in an engineering way. By understanding the principles of manufacturing and synthesis of composite nanomaterials(organic/inorganic/ composite), students will understand the principles of analysis of materials and deal with practical applications in various fields. | ||||||||||||||||||||
15 | 1 | Advanced Materials | master, doctor | Structural Characterization of Materials by X-Ray Diffraction | 3 | This lecture introduces a crystallography and X-ray diffraction for investigating the crystal structure of materials. | ||||||||||||||||||||
16 | 2 | Advanced Materials | master, doctor | Design and Synthesis of Super Engineering Plastics | 3 | This lecture introduces a basis of synthesis and characteristics of high heat-resistant polymers (specially polyimide) | ||||||||||||||||||||
17 | 3 | Advanced Materials | master, doctor | Functional Polymers | 3 | This lecture introduces basic principles and properties of the functional polymers. This lecture also covers synthetic methods, structure-property relationship, and possible applications of the various functional polymers. | ||||||||||||||||||||
18 | 4 | Advanced Materials | master, doctor | Nanoconvergence Materials | 3 | This lecture introduces inorganic and organic nanomaterials and functional nanomaterials. | ||||||||||||||||||||
19 | 5 | Advanced Materials | master, doctor | Inorganic Chemistry | 3 | This lecture introduces a basis to help understand reactivity and characteristic of inorganic compound. | ||||||||||||||||||||
20 | 6 | Advanced Materials | master, doctor | Organometallic Chemistry | 3 | With inorganic chemistry backgrounds, not only many concepts and characteristics depending on many organic ligands but also reactivity and application of organometallic chemistry will be explained with various examples. | ||||||||||||||||||||
21 | 7 | Advanced Materials | master, doctor | Organic Semiconductor Materials | 3 | In this course, students will get familiar with the fundamental principles behind electrical/photonic properties of organic semiconductors, and will learn how those principles can be built in organic photovoltaics and organic photodiode. Upon completion, students will be able to build a solid foundation that they can later apply to real materials/devices engineering problems in related areas. | ||||||||||||||||||||
22 | 8 | Advanced Materials | master, doctor | Electrochemistry: Electrical Energy Storage and Conversion | 3 | This lecture introduces about electrochemistry and principles and applications of energy storage system, especially lithium secondary batteries. | ||||||||||||||||||||
23 | 9 | Advanced Materials | master, doctor | Introduction to Advanced Materials | 3 | This lecture introduces basic concept and possible applications of the various advanced materials such as functional polymers, organic electronic materials, and functional nano-materials. | ||||||||||||||||||||
24 | 10 | Advanced Materials | master, doctor | Chemistry for Materials | 3 | Understand basic chemistry (centered on organic and inorganic chemistry) concepts and knowledge necessary for material research, and learn to application | ||||||||||||||||||||
25 | 11 | Advanced Materials | master, doctor | Instrumental Analysis for Materials | 3 | This lecture introduces the instrumental analysis, which is important for understanding a qualitative and quantitative information on the structure and composition of the materials. This lecture covers basic operation principle of the instruments and their possible applications. | ||||||||||||||||||||
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