MATSE 280: Introduction to Engineering Materials
Homepage: http://mse280b.mse.uiuc.edu/
Textbook: "Fundamentals of Materials Science and Engineering," William D. Callister, Jr.. 2nd Ed.(special edition)
References: (available in Grainger)
1. Foundations of Materials Science and Engineering, William F.
Smith (McGraw-Hill, 1993).
2. Engineering Materials and Their Applications, R.A. Flinn and
P.K. Torjan (Wiley, 1995).
3. Engineering Materials 1, 2nd Ed., Michael Ashby and David Jones
(Pergamon, 1996).
4. Materials Selection in Mechanical Design, 2nd Ed., Ashby (Butterworth/Heinemann,
1999).
5. The Principles of Engineering Materials, Barrett, Nix and Tetelman
(Prentice, 1973) .
Catalog Description, Prerequisites and Schedule:
Introduction to the materials science and engineering of ceramics, electronic materials, metals and polymers. Bonding; crystallography; imperfections; processing and properties of semiconductors, polymers, metals, ceramics and composites; and phase diagrams. Case studies and demonstrations will be used to exemplify the lecture material. Prerequisite: Physics 112, 114 (concurrent), and Math 242. 3 hours (students may not receive credit for MatSE 200 and TAM 224 (CE 210) or ME 231). 3 hours lecture-discussion/week
Course Topics:
1. Atomic Structure
2. Atomic bonding in solids
3. Metallic, Ceramic, and Polymer Structures: ionic and metallic
crystal structures, polymer structures (crystalline, non-crystalline,
etc.), Miller indices, diffraction.
4. Defects in solids: vacancies, Frenkel and Schottky defects
in ionic systems, dislocations.
5. Diffusion: vacancy and atomic diffusion in solids (time-dependent
and time-independent)
6. Mechanical Behavior of Metals, Ceramics and Polymers
7. Deformation mechanisms - metals (dislocation motion, slip,
plasticity)
8. Strengthening/Hardening mechanisms (metals, ceramics, polymers)
9. Phase diagrams (phases, phase composition, composition, and
microstructure)
10. Kinetics of phase diagrams (brief)
11. Fracture, crack propagation, and simple failure mechanisms
(ductile-to-brittle transitions, leak-before-fail criterion, etc.)
12. Composites (isoload and isostrain cases, laminates)
13. Simplified materials selection for design, with examples (e.g.,
use of Ashby plots, design of leak-before-fail vessels, strong
but light, low-deflection/no-fail, cost optimization, etc.).
Course Objectives:
1. To recall chemical bonding, types of bonds, and arrangement
of periodic table.
2. To understand the correlation between bonding and structure,
and bonding and properties.
3. To introduce concept of crystal structure, and the myriad of
structures possible in metals and ceramics, as well as crystalline
polymers, including crystal planes and diffraction.
4. To introduce the physical origin of and demonstrate the correlation
between structure and properties of materials.
5. To introduce common crystal defects and to understand their
role in materials behavior.
6. To provide overview of mechanical behavior of ceramics, metals,
and polymers, including concepts of stress-strain curves, elastic
response and Poission effect, yielding, necking, fracture, slip
via dislocations, ductility, brittleness, strengthening mechanisms,
transformation toughening, cross-linking polymers, polymer confirmations.
To know how to estimate the effects of the physical effects on
mechanical behavior.
7. To introduce students to the concept of phases and phase diagrams,
including T-c behavior leads to different microstructures and,
hence, varying mechanical behavior due to heat treatment. To understand
effects of composition on structural and mechanical behavior,
as well as how process history effects materials properties.
8. To introduce and utilize simple concepts of crack propagation,
fast-fracture, and failure. To provide failure examples and motivate
importance of materials properties in design (e.g., importance
fracture toughness, KIc,).
9. To introduce mechanical response of composite materials and
to use this information in simple examples of design and failure.
10. To use simplified materials selection concepts for design
purposes.
11. To give student broad introductory knowledge of how materials
properties ultimately affect engineering design in their respective
disciplines, and how such properties lead to limitations.
Course Outcomes:
1. Given type of material (ceramic, metal, polymer), identify
type of bonding present, types of crystal structure expected,
and expected mechanical responses.
2. Be able to predict expected ordered structures in specific
ionic solids.
3. Utilize information about elastic and plastic deformation to
predict loads or strains that lead to yielding, necking, or fracture.
Identify generic differences between stress-strain response in
ceramics, metals, crystalline and non-crystalline polymers, and
tissue.
4. Identify common defects in a material, when they are to be
expected, and know how they affect material's mechanical properties.
5. Know types of dislocation, how they move, what strain-fields
occur and how dislocations interact, what effects are created
in crystals when they move, and how they lead to plastic deformation.
6. Understand and identify the stress-strain response of ceramics,
metals, and polymers, and know generally how these are altered
by strengthening/hardening mechanisms, alloying, etc.
7. Be able to identify phases (and their abundance), eutectics,
eutectoid, and peritectic reactions in T-c diagrams, as well as
identify simple microstructures that can occur (including possible
effects on mechanical response).
8. Utilize concepts of crack propagation and fast-fracture and
ductile-to-brittle effects to predict failure of brittle solids,
and experience these in simple measurement of design problem.
9. Utilize material index parameters to select materials appropriate
to simple design problems, including yielding and fast-fracture.
Assessment Tools:
1. Homework problems involving application of each topic.
2. Three written examinations (one in-class and two more extended
take-home) Exams are designed to test the student's understanding
of concepts and their ability to apply his/her knowledge.
Contribution of Course to Meeting the Professional Component: 100%
Prepared by:
Duane D. Johnson, December, 2000, concurred in by John Weaver,
March, 2001