1 / 35

Review: FE Exam

Review: FE Exam. Text: “Materials Science and Engineering: An Introduction,” 6 th ed., William D. Callister, Jr., Wiley, 2003. Review: FE Exam. Part 1 – atomic structure & bonding What holds materials together? Part 2 – Imperfections in solids How are they packed?

apowers
Download Presentation

Review: FE Exam

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Review: FE Exam • Text: “Materials Science and Engineering: An Introduction,” 6th ed., William D. Callister, Jr., Wiley, 2003.

  2. Review: FE Exam • Part 1 – atomic structure & bonding • What holds materials together? • Part 2 – Imperfections in solids • How are they packed? • Part 3 – mechanical properties • How do they deform?

  3. Review: Chapter 1 – Introduction • Types of Materials • Metals • Polymers • Ceramics

  4. Review: Chapt 2-Atomic Structure • Atomic Number, Atomic Weight, etc. • Periodic table • Electron Structure - valence electrons – unfilled shells • Bonding • ionic • covalent • metallic • van der Waals

  5. Review: Chapt 3 – Crystal Structures • Unit Cell • Metals • BCC • FCC • HCP • Atomic packing factor • Coordination number • Crystallographic directions [uvw] families of directions <uvw> • Linear density of atoms (ld) = atoms/unit length

  6. Review: Chapt 3 – Crystal Structures (cont.) • Miller indices of planes (hkl) families of planes {hkl} • Planar density (pd) = # of atoms/ unit area (pd) = S.A. atoms/S.A. unit cell • X-Ray Diffraction • Bragg’s law

  7. Review: Chapter 4 • Imperfections • Point defects • Interstitial • Vacancy • Substitution • Solid solutions • Line defects • Edge dislocation - Burgers vector perpendicular to dislocation line • Screw dislocation - Burgers vector parallel to dislocation line • Planar defects • Twin • Stacking fault • Grain Boundary

  8. Review: Chapter 4 (cont.) • Microscopy • Optical • Electron Microscopy • Sample Prep – polishing & etching

  9. Review: Chapter 5 • Diffusion • Vacancy diffusion • Interstitial diffusion • Fick’s First Law Second Law • Temp effect • Slab- non-steady state

  10. Review: Chapter 19 • Thermal Properties • Heat Capacity • C = dQ/dT Cp > Cv • phonons • thermal expansion coefficient • l/l = l T • thermal conduction of heat • q = -k (dT/dx) • k = heat transfer coefficient

  11. Review: Chapter 6Mechanical Properties • Stress vs. strain • Hooke’s law s = E e TS y F E

  12. Review: Chapter 6 • Poisson’s Ratio • Toughness • Resilience • Hardness

  13. Review – Chapter 7 Dislocations and Strengthening Mechanisms • Deformation by motion of dislocations • Slip plane – plane of easiest deformation • Slip direction – direction of easiest slippage • Slip system – direction and plane • Applied stress must be resolved along slip direction •  =  cos cos • Twinning • Mechanism of strengthening • Grain size reduction • Solid-solution hardening • impurities reduce mobility of dislocations • Strain hardening %CW = 100 x (A0-Af)/A0 • Recovery, recrystallization, & grain growth

  14. Review – Chapter 8 Fracture – failure • Ductile fracture • Large deformations • cone & cup • small necked regions • Brittle fracture • Almost no deformation other than failure • transgranular – within grain • intergranular- between grains

  15. Review, Chapter 8 (cont.) • Griffith Crack - Stress concentration • Critical stress • Fatigue – cyclic stress • Creep

  16. Review- Chapter 9 Phase Diagrams • Isomorphous system • 1. How many & which phases • 2. Use tie line to read compositions • 3. Use lever rule to get weight fractions

  17. Review- Chapter 9 • binary eutectic system • 1. How many & which phases • 2. Use tie line to read compositions • 3. Use lever rule to get weight fractions

  18. cool cool cool heat heat heat Review- Chapter 9 (cont.) • Eutectic L S1+S2 • Eutectoid S1 S2+S3 • Peritectic S1+L S2 • Hypoeutectoid • Hypereutectoid

  19. Review - Chapter 10 Rate of Phase Transformation • Nucleation process

  20. Review - Chapter 10 (cont) • Phase transformations vs. temperature and time • Pearlite • Martensite • Bainite • Spheroidite Chapter 11 • Heat Treatments

  21. Review – Chapter 11 Fabrication of Metals • Forming • Forging • Rolling • Extrusion • Drawing • Casting • Powder metallurgy • Welding • Machining • Alloy Nomenclature • Cast Irons – addition of Si catalyzes graphite formation • Refractories

  22. Review – Chapter 12 Ceramics • Crystal structures • oxygen larger – generally in FCC lattice • cations go in lattice sites based on • size • stoichiometry • charge balance • bond hybridization • no good slip planes – brittle failure • Silicates • built up of SiO44- • layered • countercations to neutralize charge

  23. Chapter 12 – Ceramics • Carbon forms • diamond • graphite • fullerenes • amorphous • Lattice imperfections • Frenkel defect – cation displaced into interstitial site • Schottky defect – missing cation/anion pair • Phase diagrams • Mechanical properties

  24. Chapter 13 – Ceramics (cont) • Glasses • amorphous sodium or borosilicates • Forming • pressing • drawing • blowing • Clay products - forming • Hydroplastic forming • Slip casting • Refractories • Powder pressing • Cements • Advanced ceramics

  25. Chapter 14 – Polymers • Types of polymers • Commodity plastics • PE = Polyethylene • PS = Polystyrene • PP = Polypropylene • PVC = Poly(vinyl chloride) • PET = Poly(ethylene terephthalate) • Specialty or Engineering Plastics • Teflon (PTFE) = Poly(tetrafluoroethylene) • PC = Polycarbonate (Lexan) • Polysulfones • Polyesters and Polyamides (Nylon)

  26. Chapter 14 – Polymers • Molecular Weight • Actually a molecular weight distribution • Mn = Number-averaged molecular weight • Mw = Weight-averaged molecular weight • Polydispersity = Mw/Mn • A measure of the width of the distribution • Chain Shapes • linear • branched • crosslinked • network

  27. Chapter 14 & 15 – Polymers • Isomerism • Isotactic • Syndiotactic • Atactic • Cis vs. Trans • Copolymers • Random • Alternating • Block • Crystallinity • Spherulites

  28. Chapter 16 – Composites • Combine materials with objective of getting a more desirable combination of properties • Dispersed phase • Matrix • Particle reinforced • large particle • dispersion strengthened • Rule of mixtures • Upper limit Ec(u) = EmVm + EpVp • Lower limit

  29. Chapter 16 – Composites • Reinforced concrete • Prestressed concrete • Fiber reinforced • Short vs. long fibers • Critical length • allignment

  30. Chapter 18 – Electrical Properties Definitions • R = resistance = Ohms •  = RA/l = resistivity = ohm meter •  = 1/ = conductivity • C = Q/V = capacitance • r = /o = dielectric constant

  31. Chapter 18 – Electrical Properties • Energy Bands – valance vs. conduction • Conductor – no band gap • Insulator – wide gap • Semiconductor – narrow gap • Intrinsic – pure or compound • Electron vs. hole (which carries charge) • Extrinsic (doped) • n-type – donor levels – extra electrons • p-type – acceptor levels – extra holes • Microelectronics • pn junction – rectifier diode • npn transistor

  32. Chapter 20 – Superconductivity • Tc = temperature below which superconducting = critical temperature Jc = critical current density if J > Jc not superconducting Hc = critical magnetic field if H > Hc not superconducting • Meissner Effect - Superconductors expel magnetic fields

  33. Chapter 21 – Optical Properties • Electromagnetic radiation • Angle of refraction at interface

  34. Chapter 21 – Optical Properties • Light interaction with solids • Reflection • Absorption • Scattering • Transmission • Semiconductors – absorb light with energy greater than band gap • Luminescence – emission of light by a material • phosphorescence = If very stable (long-lived = >10-8 s) • fluorescence = If less stable (<10-8 s) • LASERS – coherent light • Fiber optics

  35. Questions??? • Contact Prof. David Rethwisch to discuss questions. • office 4139 SC • Phone 335-1413 • email david-rethwisch@uiowa.edu

More Related