Chapter 14

1. Chapter 14 The Group 14 Elements

2. Group 14 Elements • Carbon • nonmetal • Silicon and Germanium • semimetals • Tin and Lead • weakly, electropositive metals

3. Group 14 Properties • Ability to form network covalent bonding and to catenate Carbon (graphite) Dichlorodimethyltin(IV)

4. Group Trends • Melting and boiling points

5. Oxidation States • Multiple oxidation states are common • +4 for all the elements • covalent bonding • CO2 • -4 for C, Si, and Ge • covalent bonding • CH4 • +2 for Sn and Pb • ionic bonding • PbF2

6. Stability of Oxidation States • Frost diagram Most stable? Most reducing? Most oxidizing?

7. Carbon • Three common allotropes • Diamond • Graphite • Fullerenes and carbon nanotubes

8. Diamond • Covalent network of tetrahedrally, arranged covalent bonds

9. Diamond History • Graphite and diamond were thought to be two, different substances • In 1814, Humphry Davy burned his wife’s diamond to prove it was indeed carbon C(s) + O2(g)  CO2(g)

10. Diamond • Electrical insulator • Very good thermal conductor • High melting point • 4000°C Regular diamond (cubic) Lonsdaleite (hexagonal)

11. Diamonds in Nature • Found predominantly in Africa • Zaire is the largest producer • 29% • Russia • 22% • South Africa is the largest in terms of gem-quality • 17%

12. Diamonds in Nature • Crater of Diamonds State Park • Murfreesboro, Arkansas • http://www.craterofdiamondsstatepark.com/

13. Synthetic Diamonds • Can make synthetic diamonds from graphite by adding heat (1600°C) and pressure (5 GPa) Tracy Hall GE

14. Synthetic Diamonds • Thin films of diamonds can be made at low temperatures Diamond “Jet” Reactor

15. Synthetic Diamonds • New methods have become available to produce more gem-quality stones

16. Diamond Uses • Drill bits and saws • Surgical knife coatings • Computer chip coatings • Jewlery

17. Graphite • Hexagonal layers of covalently bound carbon • similar to benzene • delocalized pi system

18. Graphite Layers • Very weak interactions between the layers • 335 pm interlayer distance • van der Waals radius is ~150 pm • abab arrangment

19. Graphite Properties • Excellent conductor in two dimensions • due to the electron delocalization • Excellent lubricant • sheets “slide” • Absorber of gas

20. Graphite Reactivity • More thermodynamically stable than diamond • More kinetically reactive than diamond • Forms intercalation compounds

21. Graphite Sources • Mining • China • Siberia • North and South Korea

22. Graphite Production • Acheson Process 2500°C, 30 hours

23. Graphite Uses • Lubricants • Electrodes • Lead pencils • clay mixtures • hard mixtures “2H” • soft mixtures “HB”

24. Fullerenes • Carbon atoms arranged in a spherical or ellipsoidal structure • five and six-membered rings C70 C60, Buckminsterfullerene

25. Fullerenes • Named after R. Buckminster Fuller R. Buckminster Fuller (1895-1983) Buckminster Fuller’s Dome 1967 Montréal Expo

26. Discovery of Fullerenes • David Huffman and Wolfgang Krätschmer • 1982

27. Discovery of Fullerenes • Kroto, Curl, and Smalley

28. Discovery of Fullerenes • Kroto, Curl, and Smalley

29. Fullerene Production • Huffman and Krätschmer

30. Fullerene Properties • very weak intermolecular forces • sublime when heated • soluble in most nonpolar solvents • give bright colors in solution

31. Fullerene Properties • C60 crystal lattice (fcc) • low density, 1.5 g/cm3 • non-conductors of electricity • strong absorber of light

32. Fullerene Chemistry • Interstitial • superconductors [Rb+]3[C603-] superconductor

33. Fullerene Chemistry • Metal encapsulation • Li@C82 • He@C60

34. Fullerene Chemistry • Reaction with gases C60(s) + 30F2(g)  C60F60(s)

35. Cluster Sizes • Many different sizes

36. Carbon Nanotubes • Sumio Iijima • 1991

37. Nanotube Types • Single-walled (SWNT) • Multi-walled (MWNT)

38. Nanotube Properties • excellent conductor • molecular storage

39. Impure Carbon • Amorphous carbon (coke) • made by heating coal in an inert atmosphere • mostly graphite with some hydrogen impurities • used in iron production • removes oxygen • 5 x 108 tons per year

40. Impure Carbon • Carbon black • fine, powdered carbon • 3.65 x 109 tons annually

41. Impure Carbon • Activated carbon • high surface area • 103 m2/g • removes impurities from organic reactions • decolorizes chemicals

42. Carbon Isotopes • Three isotopes • carbon-12 (98.89 %) • carbon-13 (1.11 %) • carbon-14 (0.0000001%) • radioactive • t1/2 = 5.7 x 103 years

43. 14C Radioactive Dating

44. Carbon Chemistry • Two important properties • catenation • a bonding capacity greater than or equal to 2 • an ability of the element to bond to itself • a kinetic inertness of the catenated compound toward or molecules and ions • multiple bonding

45. Catenation • An ability of an element to bond with itself

46. Bond Energies • Important in determining the reactivity and/or relative stabilities of products CH4(g) + 4F2(g)  CF4(g) + 4HF(g) not CF4(g) + 4HF(g)  CH4(g) + 4F2(g)

47. Carbides • Binary compounds of carbon with more electropositive elements • typically hard with high melting points • three types: • ionic • covalent • metallic

48. Ionic Carbides • Formed by the most electropositive elements • alkali and alkaline earth metals • aluminum • Only reactive carbides Na2C2(s) + 2H2O(l)  2NaOH(aq) + C2H2(g) Al4C3(s) + 12H2O(l)  4Al(OH)3(s) + 3CH4(g)

49. Covalent Carbides • Few examples • silicon carbide and boron carbide • only important nonoxide ceramic • 7 x 105 tons produced annually SiO2(s) + 3C(s)  SiC(s) + 2CO(g)

50. Covalent Carbides • Silicon carbide uses • grinding and polishing agents • high-temperature materials applications • mirror backings • body armor