1. Chapter 13 - 1 ISSUES TO ADDRESS... How are metal alloys classified and what are their common applications? Chapter 13: Types and Applications of Materials How do we classify ceramics? What are some applications of ceramics? What are the various types/classifications of polymers?

2. Chapter 13 - 2 Adapted from Fig. 13.1, Callister & Rethwisch 4e. Classification of Metal Alloys Metal Alloys Steels FerrousNonferrous Cast Irons <1.4wt%C3-4.5wt%C _______ _________ __________ ___________ Fe 3 C cementite 1600 1400 1200 1000 800 600 400 0 1234566.7 L  austenite  +L+L  +Fe 3 C  ferrite  +Fe 3 C  +  L+Fe 3 C  (Fe) C o, wt% C Eutectic: Eutectoid: 0.76 4.30 727ºC 1148ºC T(ºC) microstructure: ferrite, graphite/cementite Adapted from Fig. 10.28, Callister & Rethwisch 4e. (Fig. 10.28 adapted from Binary Alloy Phase Diagrams, 2nd ed., Vol. 1, T.B. Massalski (Ed.-in- Chief), ASM International, Materials Park, OH, 1990.)

3. Chapter 13 - 3 Based on data provided in Tables 13.1(b), 13.2(b), 13.3, and 13.4, Callister & Rethwisch 4e. Steels Low Alloy High Alloy low carbon <0.25 wt% C Med carbon 0.25-0.6 wt% C high carbon 0.6-1.4 wt% C Usesauto struc. sheet bridges towers press. vessels crank shafts bolts hammers blades pistons gears wear applic. wear applic. drills saws dies high T applic. turbines furnaces Very corros. resistant Example101043101040434010954190304, 409 Additionsnone Cr,V Ni, Mo none Cr, Ni Mo none Cr, V, Mo, W Cr, Ni, Mo plainHSLAplain heat treatable plaintool stainless Name Hardenability 0++++ +++varies TS -0++++ varies EL ++0----++ increasing strength, cost, decreasing ductility

4. Chapter 13 - 4 Refinement of Steel from Ore Iron Ore ________ _____________ _______________________  C+O2O2  CO 2 +C  2CO CaCO 3  CaO+CO 2 CaO + SiO 2 + Al 2 O 3  slag purification reduction of iron ore to metal heat generation Molten iron BLAST FURNACE slag air layers of ______ and __________ gas refractory vessel

5. Chapter 13 - 5 Ferrous Alloys Iron-based alloys Nomenclature for steels (AISI/SAE) 10xx____________________ 11xxPlain Carbon Steels (resulfurized for machinability) 15xxMn (1.00 - 1.65%) 40xxMo (0.20 ~ 0.30%) 43xxNi (1.65 - 2.00%), Cr (0.40 - 0.90%), Mo (0.20 - 0.30%) 44xxMo (0.5%) where xx is wt% C x 100 example: 1060 steel – plain carbon steel with 0.60 wt% C ____________________ >11% Cr Steels Cast Irons

6. Chapter 13 - 6 Cast Irons Ferrous alloys with > ____________ –more _________________________ Low melting – relatively easy to cast Generally brittle Cementite decomposes to _____ + ________ Fe 3 C  3 Fe (  ) + C (__________) –generally a slow process

7. Chapter 13 - 7 Fe-C True Equilibrium Diagram Adapted from Fig. 13.2, Callister & Rethwisch 4e. [Fig. 13.2 adapted from Binary Alloy Phase Diagrams, 2nd ed., Vol. 1, T.B. Massalski (Ed.- in-Chief), ASM International, Materials Park, OH, 1990.] 1600 1400 1200 1000 800 600 400 0 1234 90 L  +L +L  + Graphite Liquid + Graphite (Fe) C, wt% C 0.65 740ºC T(ºC)  + Graphite 100 1153ºC  Austenite 4.2 wt% C  Graphite formation promoted by __________

8. Chapter 13 - 8 Types of Cast Iron Adapted from Fig. 13.3(a) & (b), Callister & Rethwisch 4e. ______ iron _________________ weak & brittle in tension stronger in compression excellent _________ dampening wear resistant ________ iron add Mg and/or Ce graphite as ________ not flakes matrix often pearlite – stronger but less ductile

9. Chapter 13 - 9 Types of Cast Iron (cont.) Adapted from Fig. 13.3(c) & (d), Callister & Rethwisch 4e. White iron < 1 wt% Si pearlite + ________ very hard and _______ __________ iron heat treat white iron at 800-900ºC graphite in __________ reasonably strong and ductile

10. Chapter 13 - 10 Types of Cast Iron (cont.) Adapted from Fig. 13.3(e), Callister & Rethwisch 4e. Compacted _________ iron relatively high _________________ good resistance to thermal shock lower oxidation at elevated temperatures

11. Chapter 13 - 11 Production of Cast Irons Adapted from Fig.13.5, Callister & Rethwisch 4e.

12. Chapter 13 - 12 Limitations of Ferrous Alloys 1)Relatively high densities 2)Relatively low electrical conductivities 3)Generally poor corrosion resistance

13. Chapter 13 - 13 Based on discussion and data provided in Section 13.3, Callister & Rethwisch 4e. Nonferrous Alloys NonFerrous Alloys Al Alloys -low  : 2.7 g/cm 3 -Cu, Mg, Si, Mn, Zn additions -solid sol. or precip. strengthened (struct. aircraft parts & packaging) Mg Alloys -very low  : 1.7g/cm 3 -ignites easily -aircraft, missiles Refractory metals -high melting T’s -Nb, Mo, W, Ta Noble metals -Ag, Au, Pt -oxid./corr. resistant Ti Alloys -relatively low  : 4.5 g/cm 3 vs 7.9 for steel -reactive at high T’s -space applic. Cu Alloys Brass : Zn is subst. impurity (costume jewelry, coins, corrosion resistant) Bronze: Sn, Al, Si, Ni are subst. impurities (bushings, landing gear) Cu-Be: precip. hardened for strength

14. Chapter 13 - 14 GlassesClay products RefractoriesAbrasivesCementsAdvanced ceramics -optical -composite reinforce -containers/ household -whiteware -structural -bricks for high T (furnaces) -sandpaper -cutting -polishing -composites -structural -engine rotors valves bearings -sensors Adapted from Fig. 13.7 and discussion in Section 13.4-20, Callister & Rethwisch 4e. Classification of Ceramics Ceramic Materials

15. Chapter 13 - 15 tensile force A o A d die Die blanks: -- Need wear ___________ properties! Die surface: -- 4  m ________________ diamond particles that are __________ onto a cemented ___________________ substrate. -- polycrystalline _________ gives uniform hardness in all directions to reduce wear. Adapted from Fig. 14.2(d), Callister & Rethwisch 4e. Courtesy Martin Deakins, GE Superabrasives, Worthington, OH. Used with permission. Ceramics Application: Die Blanks

16. Chapter 13 - 16 Tools: -- for grinding glass, __________, carbide, ceramics -- for cutting Si wafers -- for oil drilling blades oil drill bits Single crystal diamonds polycrystalline diamonds in a resin matrix. Photos courtesy Martin Deakins, GE Superabrasives, Worthington, OH. Used with permission. Ceramics Application: Cutting Tools Materials: -- manufactured single crystal or ____________ diamonds in a metal or resin matrix. -- polycrystalline diamonds _________ by microfracturing along cleavage planes.

17. Chapter 13 - 17 Example: ZrO 2 as an ________ sensor Principle: Increase diffusion rate of _______ to produce rapid response of sensor signal to change in __________ concentration Ceramics Application: Sensors A substituting Ca 2+ ion removes a Zr 4+ ion and an O 2- ion. Ca 2+ Approach: Add ______________________: -- increases O 2- vacancies -- increases O 2- diffusion rate reference gas at fixed oxygen content O 2- diffusion gas with an unknown, higher oxygen content - + voltage difference produced! sensor Operation: -- voltage ________ produced when O 2- ions diffuse from the external surface through the sensor to the reference gas surface. -- magnitude of _________ difference  partial pressure of oxygen at the external surface

18. Chapter 13 - 18 Materials to be used at high temperatures (e.g., in ______________________________). Consider the Silica (SiO 2 ) - Alumina (Al 2 O 3 ) system. Silica _________ - silica rich - small additions of alumina depress melting temperature (_________________): Refractories Composition (wt% alumina) T(ºC) 1400 1600 1800 2000 2200 204060801000 alumina + mullite + L mullite Liquid (L)(L) mullite +crystobalite + L alumina + L 3Al 2 O 3 -2SiO 2 Fig. 10.26, Callister & Rethwisch 4e. (Fig. 10.26 adapted from F.J. Klug and R.H. Doremus, J. Am. Cer. Soc. 70(10), p. 758, 1987.)

19. Chapter 13 - 19 Advanced Ceramics: Materials for Automobile Engines Advantages: –Operate at ______ temperatures – high efficiencies –___________________ –Operate without a cooling system –Lower weights than current engines Disadvantages: –Ceramic materials are __________ –Difficult to remove internal voids (that weaken structures) –_______ parts are difficult to form and machine Potential candidate materials: ___________________ Possible engine parts: engine block & piston coatings

20. Chapter 13 - 20 Advanced Ceramics: Materials for Ceramic Armor Components: -- __________________ -- Backing sheet Properties/Materials: -- Facing plates -- _______________ — fracture high-velocity projectile — Al 2 O 3, B 4 C, SiC, TiB 2 -- Backing sheets -- ________________ — deform and absorb remaining energy — aluminum, synthetic fiber laminates

21. Chapter 13 - 21 Polymer Types – Fibers Fibers - length/diameter >100 Primary use is ____________. Fiber characteristics: –___________________________ –high degrees of crystallinity –structures containing ______ groups Formed by spinning – extrude polymer through a ______________ (a die containing many small orifices) – the spun fibers are drawn under tension – leads to highly aligned chains - _________________

22. Chapter 13 - 22 Polymer Types – Miscellaneous _______ – thin polymer films applied to surfaces – i.e., paints, varnishes –______________________________ –decorative – improves appearance –______________________________ Adhesives – bonds two solid materials (___________) – bonding types: 1. Secondary – van der Waals forces 2. _________________________________________ ______ – produced by blown film extrusion ______ – gas bubbles incorporated into plastic

23. Chapter 13 - 23 Advanced Polymers Molecular weight ca. ____________ Outstanding properties –______________________ –resistance to wear/abrasion –______________________ –self-lubricating surface Important applications –___________________ –golf ball covers –hip implants (acetabular cup) UHMWPE Adapted from chapter- opening photograph, Chapter 22, Callister 7e. Ultrahigh Molecular Weight Polyethylene (UHMWPE)

24. Chapter 13 - 24 Advanced Polymers styrene ________ Thermoplastic Elastomers Styrene-butadiene _______________ ________ component domain soft component domain Fig. 13.14, Callister & Rethwisch 4e. (Fig. 13.14 adapted from the Science and Engineering of Materials, 5th Ed., D.R. Askeland and P.P. Phule, Thomson Learning, 2006.) Fig. 13.13(a), Callister & Rethwisch 4e.

25. Chapter 13 - 25 Ferrous alloys: steels and cast irons Non-ferrous alloys: -- Cu, Al, Ti, and Mg alloys; refractory alloys; and noble metals. Categories of ceramics: -- glasses -- clay products -- refractories -- cements -- advanced ceramics Summary Polymer applications -- elastomers -- fibers -- coatings-- adhesives -- films-- foams -- advanced polymeric materials