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  • 충북대학교
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Curriculum
Introduction

 


The Department offers various programs concerning materials processing, structure-property of materials, thermodynamics, ceramics, electronic & magnetic materials, semi-conductor processing, etc. Also, graduate degree programs for M.S. and PhD. degrees are offered. Current research fields cover ceramics powder processing, metallography and design of alloys, display materials and various electronic & magnetic materials and computer simulation of metal fabrication processes.

 

Credits Requirements for graduate

The department curriculum has three components: Liberal education requirements(36 Credits), a major(75 Credits), and electives.

 

Curriculum
Yr-Sem-R/E Course (Credit) Yr-Sem-R/E Course (Credit)
  1-2-R Introduction to Intelligent Engineering Design (3)
2-1-R Materials Lab.Ⅰ (2)
2-1-E Engineering MathematicsⅠ (3)
2-1-E Principles of Materials Engineering (3)
2-1-E Physical Chemistry (3)
2-1-E Introduction to Mechanics of Materials (3)
2-1-E Basics of Quantum Physics (3)
2-2-R Materials Lab. Ⅱ (2)
2-2-E Ceramic Materials Processing (3)
2-2-E Semiconductor Processing (3)
2-2-E Thermodynamics of Materials (3)
2-2-E Basics of Electric Circuits (3)
2-2-E Basics of Electromagnetism (3)
3-1-R Materials Lab. Ⅲ (2)
3-1-E Ceramic Phase Equilibrium (3)
3-1-E Phase Transformation (3)
3-1-E Thin Film Process (3)
3-1-E Electric and Magnetic Materials (3)
3-1-E Materials for Energy Chemistry (3)
3-2-R Materials Lab. Ⅳ (2)
3-2-E Physics of Materials (3)
3-2-E Iron and Steel Making (3)
3-2-E Optoelectronic Materials (3)
3-2-E X-Ray Diffration and Analysis (3)
3-2-E Ferrous Alloys
4-1-R Materials Lab. Ⅴ (2)
4-1-E Introduction to Joining and Welding Processes (3)
4-1-E Electronic Ceramics(Capstone Design) (3)
4-1-E Mechanical Behavior of Material (3)
4-1-E Nonferrous Alloys (3)
4-1-E Statistical Process Control (3)
4-1-E Industry-Academic Seminar (3)
4-2-R Capstone Design of Advanced Materials Engineering (3)
4-2-E Surface Treatment Engineering (3)
4-2-E Composite Materials (3)
4-2-E Design of Casting and Forming (3)
4-2-E Nano-Material and Its Application (3)

 

 

Courses Abstract
Introduction to Intelligent Engineering Design This course introduces the fundamental knowledge of materials and their applications in advanced technologies. The goal of this course is to develop the creative design abilities and skills of students in solving materials science and engineering problems.
Materials Lab.Ⅰ Introduction to experimental methods in mechanical behavior and design of materials.
Engineering MathematicsⅠ This course presents techniques for solving and approximating solutions to ordinary differential equations. It is primarily for student in disciplines which emphasize and contains 1st and 2nd order equations, Laplace transformation, boundary value problems. etc.
Principles of Materials Engineering focuses on understanding, designing, and producing technology-enabling materials by analyzing the relationships among the synthesis and processing of materials, their properties, and their detailed structure. This includes a wide range of materials such as metals, polymers, ceramics, and semiconductors. Solid-state science and engineering focuses on understanding and modifying the properties of solids from the viewpoint of the fundamental physics of the atomic and electronic structure.
Physical Chemistry This course presents stoichiometry, thermochemistry, chemical equilibrium, thermodynamics, and transport properties.
Introduction to Mechanics of Materials The course introduces principles of solid mechanics and stresses and strains of axial, torsion, bending loading conditions. Various topics such as mechanical behaviors of structural materials and thermal stresses of electronic devices are to be analysed.
Basics of Quantum Physics Deepened by learning modern physics, establish that physics concept necessary to advanced material process, research, development
Materials Lab. Ⅱ Experiments to familiar and inventory with the knowledge of chemical metallurgy.
Ceramic Materials Processing Various processing technology for sintered ceramics and thick- and thin films are introduced. The lecture includes synthesis and characterization of fine ceramic powders, various forming technologies and sintering process. Application fields (electrical, magnetic, structural) of ceramic materials are also introduced.
Thermodynamics of Materials This lectures on phase change such as solidification melting, evaporation, The 1st, 2nd and 3rd law of thermodynamic, enthalpy, entropy, free energy, Carnot cycle and general thermodynamic phenomena etc.
Semiconductor Processing This course provides an overview of semiconductor device fabrication procedures and processing techniques. Silicon wafer fabrication, oxidation, lithography, etching, diffusion, ion implantation, film deposition methods are covered in this course.
Basics of Electric Circuits The course introduces basic theory of electronics necessary for experimental methods of materials engineering. Topics include direct current, alternating currents, basic linear circuit analysis, diodes, transistors circuits, etc.
Basics of Electromagnetism Enrichment by the electromagnetism necessary for understanding of the magnetic material, dielectric, optical, etc., and establishes a foundation for the development field of materials.
Materials Lab. Ⅲ This laboratory demonstrates the principles and experiments in the synthesis and characterization of thin film materials and semiconductors for applications in information and electronic technologies.
Ceramic Phase Equilibrium This lectures on basic principle and theory of phase diagram in binary and ternary system of ceramics.
Phase Transformation This course is designed to provide fundamental understanding in solidification, diffusion, phase transformation in metals and materials. Fick's first and second law of diffusion, fundamentals of solidification, thermodynamics of solid solution, nucleation and growth of precipitates, kinetic of phase transformation are covered in this course.
Thin Film Process This course covers fundamentals of plasma physics, and industrial applications of low pressure plasma processes. Microstructural characteristics and analysis of thin films and some important technological applications of thin films are included.
Elastic and Magnetic Materials Various metallic, semi-conducting and ceramic materials are introduced for their diverse application in electronic and magnetic fields. To understand the principles of electronic and magnetic applications of the materials, circuit theory including fundamental concept of resistance, inductance, capacitance, and their DC and AC characteristics are also introduced.
Materials for Energy Chemistry This course introduces an overview of the materials for energy devices such as fuel cell and battery. In order to understand the operation principles of the device, the electrochemistry and defect chemistry are also introduced.
Materials Lab. Ⅳ Subject accomplishment and the discussion for the test which relates in electronic material field and an originality development.
Physics of Materials Electronic structure of metals, semiconductors, and insulators are introduced focusing on the band theory. In particular, the lecture emphasizes the principles and application of semiconducting materials (intrinsic and impurity-doped) including p-n junction, diodes and transistors. Processing technology of semiconducting devices is also briefly introduced.
Iron and Steel Making This course is designed to provide principles of iron and steel making, continuous casting. It covers thermodynamics in iron and steel making process, materials in iron and steel making process, iron and steel making systems, refining of melts, stainless steel making process, and future steel making process.
Optoelectronic Materials This course helps students understand the fundamental operation principles and basic manufacturing processes of various display devices.
X-Ray Diffraction and Analysis This course covers diffraction phenomena from materials due to their structures. Basics of crystallography, diffraction physics and applications of X-ray diffractions are included. Principles of material analysis methods useful to understand materials microstructure such as EDS, XRF, XPS, AES are also introduced.
Ferrous Alloys Metallurgical characteristics manufacturing process and the industrial application of the ferrous alloys will be covered to cope with the design and processing.
This course covers the fundamental properties of ferrous materials as a basic one of metallic materials. The interrelationship between mechanical, physical properties and the microstructure will be discussed. A principal and the application of the phase transformation, including heat treatment, will be covered.
Materials Lab. Ⅴ Experiments and lectures on fabrication, designing and characterization of electronic materials.
Introduction to Joining and Welding Processes The course introduces various joining/welding processes and micro structural behaviour of materials in bonding processes. Joining of dissimilar metals and alloys, metal-ceramic bonding, soldering and brazing including electronic packaging are also to be studied. Thermal distortions and flaws in welding and brazing, reliabilities of electronic packaging are to be analysed.
Electronic Ceramics(Capstone Design) Lectures on electrical properties of semiconducting ceramics in terms of defect chemistry and electronic and ionic conductivity for the commercial application such as sensor, filter, resonator and memory devices.
Mechanical Behavior of Material An advanced materials science course dealing with the response of materials to applied forces. Mechanical fundamentals; stress-strain relationships for elastic behavior; theory of plasticity.  Metallurgical fundamentals; plastic deformation, dislocation theory; strengthening mechanisms. Mechanical behavior of polymers.  Applications to materials testing.
Nonferrous Alloys Metallurgical characteristics manufacturing process and the industrial application of the non-ferrous alloys will be covered to cope with the design and processing. This course covers the fundamental properties of non-ferrous materials as a basic one of metallic materials. The interrelationship between mechanical, physical properties and the microstructure will be discussed. A principal and the application of the phase transformation, including heat treatment, will be covered.
Statistical Process Control This course is designed to provide distributions, measures of central tendency, dispersion and shape, the normal distribution; experiments to compare means, standard errors, confidence intervals; effects of departure from assumption; method of least squares, regression, correlation, assumptions and limitations; basic ideas of experimental design, and basic computer graphics.
Industry-Academic Seminar The objective of this subject is to learn the state-of-art technology and trends in industry by the invited lecturers from business and government organization and to reduce the distance between academic education and industry. In addition, the information and expectation for the recruit is provided by them.
Capstone Design of Advanced Materials Engineering This course is to promote understanding and summarizing of real problems in materials engineering, creativity in solving open-ended, ill-defined problems, and practice in thinking and written and oral communication skills. It covers research documentation, proposal, progress reports, oral presentations, formal report, and discussion of topics related to problem solving and professional development.
Surface Treatment Engineering The last process of material process is surface treatment. In this subject, the principles of surface treatment of materials are lectured which contains basic physical chemistry, electroplating, chemical plating, dip plating in molten metals, anodizing, corrosion and its protection, cementation, conversion coating, etc.
Composite Materials Principles, processing and applications of polymer, metal and ceramic matrix composite materials are introduced. Also advanced materials such as nano-composite, CNT, graphene are studied. Using mechanics and strength of materials mechanical and fracture behaviors of composites are analyzed in this course.
Design of Casting and Forming Metal casting, casting method and material, special casting, and other related field will be covered in this course.
Nano-Material and Its Application Nanomaterial fabrication and its characterization will be mainly covered in this class. The objective is coupled with the fundamental objective, which is to understand the relationship between thermodynamics, phase transformation, crystallography and other material theory. Also advanced materials such as cabo nanotube, graphene and other new materials and its application will be introduced.
InternshipⅠ,Ⅱ,Ⅲ,Ⅳ Site actual training of the students to lead and the objection which it learns from the university take a triangular position, necessary knowledge and technical find from thread industry.
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