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7 - MGE 501 3(3-0-9) (Metals Testing and Characterization) LNG 550 2(1-2-6) (Remedial English Course For Post Graduate Students) LNG 600 3(2-2-9) (Insessional English Course for Post Graduate Students) LNG 550 / LNG LNG 600 /

. 12 PRE 651 3(3-0-9) (Microstructural Evolution and Its Resultant Properties in Metals) PRE 652 3(3-0-9) (Transport Phenomena in Process Metallurgy) MGE 631 3(3-0-9) (Thermodynamics of Solids) PRE 747 3(3-0-9) (Research Methodology) . 15 21 MGE 611 3(3-0-9) (Multicomponent Phase Equilibria) MGE 612 3(3-0-9) (Transformation of Solids) MGE 621 3(3-0-9) (Fracture Mechanics) MGE 622 3(3-0-9) (Deformation Mechanisms in crystalline Solids) MGE 623 3(3-0-9) (Mechanical Behavior of Metals) MGE 632 3(3-0-9) (Applied Chemical Metallurgy) MGE 633 3(3-0-9) (Ferrous Metallurgy and Its Processing) MGE 634 3(3-0-9) (Nonferrous Metallurgy and Its Processing)

8 MGE 641 3(3-0-9) (Methods of Surface and Interface Characterization) MGE 642 3(3-0-9) (Diffraction and Structure) MGE 643 3(3-0-9) (Quantitative Analysis of Microstructure) MGE 651 3(3-0-9) (Materials Selection, Design, and Economics) MGE 652 3(3-0-9) (Casting Design) MGE 653 3(3-0-9) (Materials for Elevated Temperature Service) MGE 654 3(3-0-9) (Biomaterials and Biocompactibility) MGE 655 3(3-0-9) (Industrial Ecology) MGE 661 3(3-0-9) (Corrosion and Its Preventions) MGE 662 3(3-0-9) (Metallurgical Failure Analysis) MGE 671 3(3-0-9) (Heat Treatment of Ferrous) MGE 672 3(3-0-9) (Heat Treatment of Non-ferrous) MGE 681 3(3-0-9) (Surface Science and Engineering) MGE 682 3(3-0-9) (Forming Process Analysis) MGE 683 3(3-0-9) (Solidification Science) MGE 684 3(3-0-9) (Advanced Foundry Engineering) MGE 685 3(3-0-9) (Powder Metallurgy) MGE 686 3(3-0-9) (Theory and Practice of Steel Manufacturing)

9 MGE 691 3(3-0-9) (Materials Performance and Reliability) MGE 692 3(3-0-9) (Analysis and Control of Materials Processes) MGE 601 1 3(3-0-9) (Special Topics I) MGE 602 2 3(3-0-9) (Special Topics II) . MGE 603 1(1-0-3) (Seminar) . / MGE 604 12 (Thesis) MGE 605 6 (Industrial Research Project)

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1 1 PRE 651 3(3-0-9) (Microstructural Evolution and Its Resultant Properties in Metals) MGE 631 3(3-0-9) (Thermodynamics of Solids) MGE xxx 1 3(3-0-9) (Elective I) MGE xxx 2 3(3-0-9) (Elective II)

12(12-0-36) / = 48 1 2

PRE 652 3(3-0-9) (Transport Phenomena in Process Metallurgy)

MGE xxx 3 3(3-0-9) (Elective III) MGE xxx 4 3(3-0-9) (Elective IV) MGE 604 3(0-6-12) (Thesis) 12(9-6-39)

/ = 54

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PRE 747 3(3-0-9) (Research Methodology) MGE xxx 5 3(3-0-9) (Elective V) MGE 604 3(0-6-12) (Thesis) 9(6-6-30)

/ = 42 2 2

MGE 603 1(1-0-3) (Seminar) MGE 604 6(0-12-24) (Thesis) 7(1-12-27)

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PRE 651 3(3-0-9) (Microstructural Evolution and Its Resultant Properties in Metals) MGE 631 3(3-0-9) (Thermodynamics of Solids) MGE xxx 1 3(3-0-9) (Elective I) MGE xxx 2 3(3-0-9) (Elective II)

12(12-0-36) / = 48 1 2

PRE 652 3(3-0-9) (Transport Phenomena in Process Metallurgy)

MGE xxx 3 3(3-0-9) (Elective III) MGE xxx 4 3(3-0-9) (Elective IV) MGE xxx 5 3(3-0-9) (Elective V)

12(12-0-36) / = 48

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PRE 747 3(3-0-9) (Research Methodology) MGE xxx 6 3(3-0-9) (Elective VI) MGE xxx 7 3(3-0-9) (Elective VII) 9(9-0-27)

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MGE 603 1(1-0-3) (Seminar) MGE 605 6(0-12-24) (Industrial Research Project) 7(1-12-27)

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2553 2554 2555 2556 2557 1 .. Ph.D. (Metallurgical Engineering) ,U. of Wisconsin 20 22 20 22 20 2 .. Ph.D. (Metallurgical Engineering) ,U. of Alabama 30 28 32 28 32 3 .

Dr.Ing. (Mechanical Engineering) , Technical U. of Munich

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2554 2555 2556 2557 2558 1 Dr. John Pearce

Ph.D. (Metallurgical Engineering) , Archaeology and Anthropology (Cambridge) and MA (Durham)

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2 . Ph.D. (Industrial Engineering) ,Texas Tech University

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Ph.D. (Production Engineering) , University of Birmingham

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Ph.D. (Metallurgical Engineering) , University of Connecticut

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5 . Ph.D. (Industrial Engineering) ,Lehigh University 6 6 6 6 6 6 .

Sc.D. (Metallurgical Engineering) , Massachusetts Institute of Technology

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3. (Curriculum Mapping) 3.1 (Curriculum Mapping)

1. 2. 3. 4.

5.

1 2 3 4 5 1 2 3 4 5 1 2 3 4 5 1 2 3 4 5 1 2 3 4 5

LNG 550 (Remedial English Course For Post Graduate Students) 2 (1-2-6)

LNG 600 (Insessional English Course for Post Graduate Students) 3 (2-2-9)

17 1. 2. 3. (1) (1) (1) (2) (2) (3) (3) (2) (4) (3) (4) (4) (5) (5) (5) 4. 5. (1) (1) / (2) (3) (2) (4) (3) (5) (4) (5)

18 3.2 (Curriculum Mapping)

1. 2. 3. 4.

5.

1 2 3 4 1 2 3 4 1 2 3 4 1 2 3 4 1 2 PRE 651 (Microstructural Evolution and Its Resultant Properties in Metals) 3(3-0-9)

PRE 652 (Transport Phenomena in Process Metallurgy) 3(3-0-9)

MGE 501 (Metals Testing and Characterization) 3(3-0-9)

MGE 631 (Thermodynamics of Solids) 3 (3-0-9)

PRE 747 (Research Methodology) 3(3-0-9)

MGE 611 (Multicomponent Phase Equilibria) 3(3-0-9)

MGE 612 (Transformation of Solids) 3(3-0-9)

MGE 621 (Fracture Mechanics) 3(3-0-9)

MGE 622 (Deformation Processing) 3(3-0-9)

19

1. 2. 3. 4.

5.

1 2 3 4 1 2 3 4 1 2 3 4 1 2 3 4 1 2 MGE 623 (Mechanical Behavior of Metals) 3 (3-0-9)

MGE 632 (Applied Chemical Metallurgy) 3(3-0-9)

MGE 633 (Ferrous Metallurgy and Its Processing) 3(3-0-9)

MGE 634 ( Nonferrous Metallurgy and Its Processing) 3(3-0-9)

MGE 642 (Diffraction and Structure) 3(3-0-9)

MGE 643 (Quantitative Analysis of Microstructure) 3(3-0-9)

MGE 651 (Materials Selection, Design, and Economics) 3(3-0-9)

MGE 652 (Casting Design) 3(3-0-9)

MGE 653 (Materials for Elevated Temperature Service) 3(3-0-9)

20

1. 2. 3. 4.

5.

1 2 3 4 1 2 3 4 1 2 3 4 1 2 3 4 1 2 MGE 654 (Biomaterials and biocompactibility) 3(3-0-9)

MGE 655 (Industrial Ecology) 3(3-0-9) MGE 661 (Corrosion and its preventions) 3(3-0-9)

MGE 662 (Metallurgical Failure Analysis) 3(3-0-9)

MGE 671 (Heat Treatment of Ferrous) 3(3-0-9)

MGE 672 (Heat Treatment of Non-ferrous) 3(3-0-9)

MGE 681 (Surface science and Engineering) 3(3-0-9)

MGE 682 (Forming Process Analysis) 3(3-0-9)

MGE 683 (Solidification Science) 3(3-0-9)

MGE 684 (Advanced Foundry Engineering) 3(3-0-9)

MGE 685 (Powder Metallurgy) 3(3-0-9)

MGE 686

21

1. 2. 3. 4.

5.

1 2 3 4 1 2 3 4 1 2 3 4 1 2 3 4 1 2 (Theory and Practice of Steel Manufacturing) 3(3-0-9) MGE 691 (Materials Performance and Reliability) 3(3-0-9)

MGE 692 (Analysis and Control of Materials Processes) 3(3-0-9)

MGE 601 1 (Special Topics I) 3(3-0-9)

MGE 602 2 (Special Topics II) 3(3-0-9)

MGE 603 (Seminar) 1(1-0-3)

MGE 604 (Thesis) 12

MGE 605 (Industrial Research Project) 6

MGE 641 (Methods of Surface and Interface Characterization) 3(3-0-9)

22 1. 2. 3. (1) (1) (1) (2) (2) (2) (3) (3) (3) (4) (4) (4) 4. 5. (1) (1) (2) (2) (3) (4)

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. LNG 550 2 (1-2-6) (Remedial English Course for Post Graduate Students) : LNG 600 This course aims to instill the background language and skills necessary for undertaking LNG 600 and to raise the students confidence in using English. There will be no predetermined focus of the course, but instead it will concentrate on those areas where the students are weakest and need most improvement. The classroom teaching and learning will be supported by self-directed learning to allow the students to improve their language and skills autonomously. LNG 600 3 (2-2-9) (Insessional English Course for Post Graduate Students)

: LNG 550 or Pass grade from placement procedure

This course aims to develop English language skills relevant to mature students in Graduate Degree Programmes in Engineering, Science and Technology. It will be based on practical skills, but will not be yet another grammar course. Rather its focus will be on the real language demands, particularly in reading and writing, faced by students in the course of their studies. It is project-focussed and simulates the stages in preparing and presenting research, from finding references to writing a final draft. The course will equip students with language learning strategies to facilitate ongoing autonomous learning and will emphasise language use not usage, real communication not classroom practice. PRE 651 3 (3-0-9) (Microstructural Evolution and Its Resultant Properties in Metals) : Topics include atomic structures, defects, diffusion, solidification, grain growth, microstructural evolution. Mechanical and physical properties of metals. Investigations include structural transitions and structure-property relationships through practical metals examples.

29 Phase equilibrium diagram. Strengthening Mechanisms. The lectures are widely illustrated with examples and applications based on ferrous and non-ferrous. PRE 652 3 (3-0-9) (Transport Phenomena in Process Metallurgy) : ( ) Principles of fluid flow, heat transfer and diffusion. Practical examples relevant to metallurgical engineering. Applications in Metallurgical Processing (heat treating, laser transformation hardening, welding, casting, single crystal growth). PRE 747 3 (3-0-9) (Research Methodology) :

Definition and Types of the Research. Research and Problem Solving. How to define the problem. How to formulate the hypothesis. Root Causes Analysis. Some techniques for hypothesis testing i.e. Significant testing, Analysis of Variance (ANOVA), Design of Experiment (DOE), PM analysis etc. MET 501 3 (3-0-9) (Metals Testing and Characterization) : Principles of metal testing and characterization include microstructure examinations, macrostructure examinations, mechanical testings, metal characterization, heat treatment of metals, non-destructive testing, and thermal analysis. MGE 611 3 (3-0-9) (Multicomponent Phase Equilibria) : : Eutectic, Peritectic, 1 2 3 Thermodynamic principles governing phase equilibria. Estimation of thermodynamic properties. One-component systems Two-component systems: eutectic, peritectic, and complex equilbria. Ssolidification and microstructure. Three-component systems: type I, II and III invariant equilibria. Applications of phase equilibria to the design of welding, heat treatment, casting, and other topics.

30 MGE 612 3 (3-0-9) (Transformation of Solids) : The basic factors that determine phase equilibria and structural characteristics of solids. Phase transformations, nucleation, recrystallization, precipitation, corrosion, and oxidation. Atomistic basis for diffusion.Analysis of diffusion kinetics in single and multiphase systems. Martensitic transformation-crystallography and microstructures. MGE 621 3 (3-0-9) (Fracture Mechanics) : Deformation and fracture mechanics of engineering materials, fracture, microstructural aspects of fracture toughness, environment assisted cracking, fatigue crack propagation, Fracture-mechanic design, analysis of engineering failures. MGE 622 3 (3-0-9) (Deformation Mechanisms in Crystalline Solids) : Deformation processing of metal Fracture mechanisms Mechanical properties at high temperature for superalloy stainless steel and heat resisting coating materials relation between chemical composition microstructure and high temperature application Effecct of alloying elements on dislocation motion Diffusion lattice Dynamic recrystallization Life prediction and remaining life assessment based on operating condition and operating time. MGE 623 3 (3-0-9) (Mechanical Behavior of Metals) : Mechanical properties and relationship. Plastic deformation of crystalline materials. Relationship of microstructures to mechanical strength. Strengthening mechanisms Characteristic of Fracture Surface , Creep theory and Fatigue theory.

31 MGE 631 3 (3-0-9) (Thermodynamics of Solids) : (Gibbs Free Energy) 2 Thermodynamics of materials science and engineering. Review of first, second and third laws of thermodynamics. Equilibrium calculations for pure substances. Equilibrium calculations involving pure substances and solutions. Behavior of solutions. Behavior of gases. Reactions involving gases. Gibbs free energy and Phase diagrams of binary systems. MGE 632 3 (3-0-9) (Applied Chemical Metallurgy) : Stoichiometry, Mass and energy balances. Complex metallurgical processes such as mineral processing, roasting, oxidation-reduction, smelting, refining, selective leaching, and electrolysis. Formation and control of slag. MGE 633 3 (3-0-9) (Ferrous Metallurgy and Its Processing) : - () Fe-C Iron and Steel making process, oxygen steelmaking process, electric furnance steelmaking, ladle metallurgy; AOD process, direct reduction and smelting processes. Casting-steel and iron. Continuous casting of steel products. Classification and basic metallurgy of cast irons and steels. Metallurgy and properties of cast irons and steels. Heat treating of cast irons and steels. Graphite formation. Phase transformation in Fe-C system. Martensitic transformation. HSLA steels and stainless steel metallurgy. MGE 634 3 (3-0-9) (Nonferrous Metallurgy and Its Processing) : Properties, manufacturing process and uses of copper alloys, aluminum alloys, magnesium alloys, and titanium alloys. Correlations between composition, microstructure, heat treatment, and properties.

32 MGE 641 3 (3-0-9) (Methods of Surface and Interface Characterization) : Principles and engineering applications of major methods of structural and chemical characterization of surfaces and interfaces, including light microscopy, color metallography techniques, polarized and Nomarski optical microscopy, scanning electron microscopy, EDS, WDS, low-energy electron diffraction. MGE 642 3 (3-0-9) (Diffraction and Structure) : Laue Bragg Reciprocal lattice Fourier transforms X-ray and neutron diffraction using Laue equations, Bragg's law, and the reciprocal lattice. Use of Fourier transforms and series to establish relations between intensity and distribution of scattering density. Applications to identification of materials, texture, small angle scattering and Rietveld analysis. Determines structure through diffraction effects: the phase problem, Patterson function, and direct methods for phase determination. Quantitative description and refinement of atomic arrangements. MGE 643 3 (3-0-9) (Quantitative Analysis of Microstructure) : A review will be presented of basic probability theory and statistical analysis, with particular emphasis on terms and definitions of a microstructure. The properties accessible to quantification, the basic stereological relationships and the mathematical foundations, and the microstructural tools needed to quantify the structure will be emphasized. Applications of quantitative metallography to problems in failure analysis, solidification, heat treatment, phase equilibria, and deformation behavior. MGE 651 3 (3-0-9) (Materials Selection, Design, and Economics) : A survey of techniques for analyzing how the choice of materials, processes, and design determine properties, performance, and cost. Topics include production and cost functions, mathematical optimization, evaluation of single and multi-attribute utility, decision analysis,

33 materials property charts, and performance indices. Students use analytical techniques to develop a plan for starting a new materials-related business. MGE 652 3 (3-0-9) (Casting Design) : Melt reactions, mold design, Coring, Problems encounter in thin sections and junctions. Dimensional variation and tolerance, solidification shrinkage, casting accuracy, surface finishing. Structure properties and defects of the finished casting. Design for die casting, corrosion resistant castings, heat resistant casting. The selection, properties, and applications of non-ferrous alloy casting. MGE 653 3 (3-0-9) (Materials for Elevated Temperature Service) : Mechanical behavior of metals and other nonmetallic materials considering composition, structure, environment, and service conditions. Structural stability. Creep and stress rupture. Deformation mechanism maps Fracture mechanisms maps Degradation of metal due to high temperature operating MGE 654 3 (3-0-9) (Biomaterials and Biocompactibility) This course presents a balanced perspective on the evolving discipline of Biomaterials Science by including information on hard biomaterials and soft biomaterials, orthopedic ideas, cardiovascular concepts, ophthalmologic ideas, and dental issues. The course will include a balance of fundamental biological concepts, materials science background, medical/clinical concerns, as well as a coverage of biomaterials past, present, and future. The aim of the course is for the student to gain a solid appreciation for the special significance of the word biomaterial as well as the rapid and exciting evolution and expansion of biomaterials science and its applications in medicine. MGE 655 3 (3-0-9) (Materials Ecology) : Quantitative techniques for life-cycle analysis of the impacts of materials extraction, processing use, and recycling; and economic analysis of materials processing, products, and markets. Student teams undertake a major case study of automobile manufacturing using the latest methods of analysis and computer-based models of materials process.

34 MGE 661 3 (3-0-9) (Corrosion and its preventions) Thermodynamics and kinetics of metallic corrosion. The common forms of corrosion and corrosion susceptibility tests. Corrosion prevention, economic considerations. High temperature oxidation. MGE 662 3 (3-0-9) (Metallurgical Failure Analysis) : Procedure for failure analysis. Investigative techniques. Distortion failures. Basic single-load fracture modes. Stress systems related to single-load fracture of ductile and brittle metals. Fatigue fracture. Wear failures. Corrosion failures. Elevated-temperature failures. Case study of metallurgical failure analysis. MGE 671 3 (3-0-9) (Heat Treatment of Ferrous) : Theories and principles of dislocation on strengthening mechanism of metals, recovery, recrystallization, and grain growth. Phase transformation of solid in metals. Surface hardening. Other heat treatment techniques emphasized on iron and steels. Equipment and quality control. MGE 672 3 (3-0-9) (Heat Treatment of Non-ferrous) : Theories and principles of dislocation on strengthening mechanism of metals emphasized on non-ferrous. Precipitation hardening Equipment and quality control. MGE 681 3 (3-0-9) (Surface Science and Engineering) : - -

35 Theory of surface reconstructions, electronic properties of surfaces, interfaces and overlayers. Characterization of surfaces by photons, electrons and ions as probes. The effect of substrate surface structure on the overlayer properties. Theoretical and experimental evaluation of surface energies, solid-liquid and solid-gas interfaces-surface potentials, colloids, sedimentation, adsorption and reaction on surfaces. Damage of the surfaces by corrosion and wear. Wear mechanisms, and categories of wear. Surface modifications by diffusion, heat treatment and by coatings, surface processing by laser, electrons and ions. MGE 682 3 (3-0-9) (Forming Process Analysis) : Plastic forming of metals, bending, forging rolling, forge rolling, drawing, sheet metal forming, forging of complicated shapes, geometry of plastic zone, formability, asymmetry of plastic deformation, Forming analysis Computer simulation of forming process. MGE 683 3 (3-0-9) (Solidification Science) : Advanced developments in various phases of the foundry and welding industries, application of scientific and engineering principles to solidification phenomena, refining, metal casting and welding problems. Nucleation and growth theory. MGE 684 3 (3-0-9) (Advanced Foundry Engineering) : Principles of liquid metal processing. Molding and casting processes. Foundry equipment and processing; melting processing, processing of castings, modeling of solidification and heat transfer, modeling of microstructural evaluation. MGE 685 3 (3-0-9) (Powder Metallurgy) : Describing the various typer of powder processing and how these affect properties of the components made. Current issues in the subject area, from high production to nanomaterials, will be discussed. Preparation and fabrication of metal powder; engineering properties and industrial uses; theory of compaction and sintering.

36 MGE 686 3 (3-0-9) (Theory and Practice of Steel Manufacturing) : In this course the theory and practice of steel products manufacturing will be reviewed, drawing upon knowledge from previous courses and the vast knowledge and experience of several experts from local industry. Topics to be studied include: carbon and alloy steels, hot-working, cold-working and the manufacture of common product forms (including both rod and bar and flat-rolled steel), and welding technology. MGE 691 3 (3-0-9) (Materials Performance and Reliability) : ( ) ( ) The failure and wear mechanisms for a variety of materials (metals, ceramics, polymers, composites and microelectroniccs) . Multi-axial failure theories. Case studies of failure mechanisms (plastic deformation, creep, fracture, fatigue, wear and corrosion). Life assessment. The methodology and techniques for reliability analysis . MGE 692 3 (3-0-9) (Analysis and Control of Materials Processes) : The fundamentals of the processing-structure property- performance relationships for casting, powder metallurgy, heat treating and coating manufacturing processes will be developed. The fundamental relationships between the process parameters and the specifications will be examined in terms of process control requirements and process capability. Process parameter measurement and control strategies will also be discussed. The course will include team projects and industrially supplied problems. MGE 601 1 3 (3-0-9) (Special Topics I) : Teach the advanced topics of current research interests in physical metallurgy. MGE 602 2 3 (3-0-9) (Special Topics II) :

37 Teach the updated and interesting topics in manufacturing community related to process metallurgy. MGE 603 1 (1-0-3) (Seminar) : Students form a group to express and discuss their experience during their industrial research project. MGE 604 12 (Thesis) : This course consists of a laboratory or field project under the supervision of a faculty member in the related approved topics. They must write up the thesis and perform final presentation. MGE 605 6 (Industrial Research Project) : 4 Every student must complete the industrial research project in manufacturing industries for 4 months. They must write up the industrial research project report and perform final presentation.