1 / 76

Chapter 10 & 11

Chapter 10 & 11. Molecular Bonds & Band Structure Semiconductors Superconductivity Lasers. Harris, “Modern Physics” Eisberg & Resnick, “Quantum Physics of Atoms, Molecules, Solids, Nuclei, and Particles ”. Outline. 10.1 Molecular Bonding (~2 atoms together) pages 334-342

varana
Télécharger la présentation

Chapter 10 & 11

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. Chapter 10 & 11 Molecular Bonds & Band Structure Semiconductors Superconductivity Lasers Harris, “Modern Physics” Eisberg & Resnick, “Quantum Physics of Atoms, Molecules, Solids, Nuclei, and Particles”

  2. Outline • 10.1 Molecular Bonding (~2 atoms together) • pages 334-342 • 11.1 Band Theory (~1023 atoms together) • pages 387-392 • 11.2 Semiconductor Theory • mainly pages 395-398 • 10.5 Superconductivity • pages 362-381 • 10.2 Stimulated Emission & Lasers • mainly pages 342-347

  3. MOLECULES(~2 atoms together)Ionic & Covalent BondsMolecular ExcitationsRotation, Vibration, Electric

  4. Ionic Bonds RNave, GSU at http://hyperphysics.phy-astr.gsu.edu/hbase/chemical/bond.html#c4

  5. Ionic Bond Energy Balance

  6. Covalent Bonds RNave, GSU at http://hyperphysics.phy-astr.gsu.edu/hbase/chemical/bond.html#c4

  7. Covalent Bonding SYM ASYM spatial spin ASYM SYM spatial spin space-symmetric tend to be closer Ref: Harris

  8. Ionic Characteristics Crystalline solids High melting & boiling point Conduct electricity when melted Many soluble in water, but not in non-polar liquids Covalent Characteristics Gases, liquids, non-crystalline solids Low melting & boiling point Poor conductors in all phases Many soluble in non-polar liquids but not water Ionic vs Covalent Bond Properties

  9. Molecular ExcitationsRotational Spectra w moment of inertia rotational A.M.

  10. Rotational Spectra Ref: Harris

  11. Molecular ExcitationsVibration

  12. Vibration (in an Electronic state)

  13. Ocean Optics: Nitrogen N2 ~ 0.3 eV ~ 0.4 eV http://hyperphysics.phy-astr.gsu.edu/hbase/quantum/atspect.html

  14. Electronic + Vibration Ref: Harris

  15. Electronic + Vibration + Rotation 2.550 eV 2.656 eV electronic excitation gap vibrational excitation gaps Ref: Eisberg&Resnick

  16. Electronic + Vibration + Rotation Vibrational Well Vibrational Well 2.656 eV depth ~ 0.063 eV electronic excitation gap vibrational excitation gaps Ref: Eisberg&Resnick

  17. Electronic, Vibration, Rotation Electronic ~ optical & UV ~ 1 – 3 eV Vibration ~ IR ~ 10ths of eV Rotation ~ microwave ~ 1000ths of eV Harris 9.24

  18. Some Molecular Constants Notes: a) vibrational frequency in table is given as f / c b) moment of inertia in table is given as hbar2/(2I) / hc

  19. SOLIDS(~10x atoms together)

  20. Isolated Atoms

  21. Diatomic Molecule

  22. Four Closely Spaced Atoms conduction band valence band

  23. Two atoms Six atoms Solid of N atoms ref: A.Baski, VCU 01SolidState041.ppt www.courses.vcu.edu/PHYS661/pdf/01SolidState041.ppt

  24. Sodium Bands vs Separation Rohlf Fig 14-4 and Slater Phys Rev 45, 794 (1934)

  25. Copper Bands vs Separation Rohlf Fig 14-6 and Kutter Phys Rev 48, 664 (1935)

  26. Differences down a column in the Periodic Table: IV-A Elements same valence config Sandin

  27. Conductors vs insulators vs semiconductors

  28. Conductors & Insulators at T=0 Harris9.35a

  29. Conductors & Insulators at T>0 Harris9.35b

  30. Semiconductors&Superconductors Rex Thorton p 395-398 p 362-381

  31. Two atoms Six atoms Solid of N atoms ref: A.Baski, VCU 01SolidState041.ppt www.courses.vcu.edu/PHYS661/pdf/01SolidState041.ppt

  32. Temperature Dependence of Resistivity

  33. Conductors & Insulators at T=0 Harris9.35a

  34. Conductors & Insulators at T>0 Harris9.35b

  35. Conductors Resistivity r increases with increasing Temp Temp t but same # conduction e-’s r Semiconductors & Insulators Resistivity r decreases with increasing Temp Temp t but more conduction e-’s r

  36. Semiconductors ~1/40 eV gap • Types • Intrinsic – by thermal excitation or high nrg photon • Photoconductive – excitation by VIS-red or IR • Extrinsic / Doped • n-type • p-type ~1 eV gap ~1-4 eV gap ~0.01 eV gap with adjustable charge carrier density

  37. Intrinsic Semiconductors Silicon Germanium RNave: http://hyperphysics.phy-astr.gsu.edu/hbase/solcon.html#solcon

  38. Doped Semiconductors lattice p-type dopants n-type dopants

  39. 5A doping in a 4A lattice Almost free, but not quite Sandin, “Modern Physics” 5A in 4A lattice 3A in 4A lattice

  40. Bands in n-doped Semiconductor 9.44

  41. Bands in p-doped Semiconductor 9.45

  42. Superconductivity First observed Kamerlingh Onnes 1911

  43. Note: The best conductors & magnetic materials tend not to be superconductors (so far) Superconductors.org Only in nanotubes

  44. Discovery of “Type II” --- CuxOy

  45. Superconductor Classifications • Type I • tend to be pure elements or simple alloys • r = 0 at T < Tcrit • Internal B = 0 (Meissner Effect) • At jinternal > jcrit, no superconductivity • At Bext > Bcrit, no superconductivity • Well explained by BCS theory • Type II • tend to be ceramic compounds • Can carry higher current densities ~ 1010 A/m2 • Mechanically harder compounds • Higher Bcrit critical fields • Above Bext > Bcrit-1, some superconductivity

  46. Superconductor Classifications

  47. Type I Bardeen, Cooper, Schrieffer 1957, 1972 “Cooper Pairs” e- e- Symmetry energy ~ -0.01 eV Q: Stot=0 or 1? L? J?

  48. Popular Bad Visualizations: correlation lengths Sn 230 nm Al 1600 Pb 83 Nb 38 Pairs are related by momentum ±p, NOT position. Best conductors  best ‘free-electrons’  no e- – lattice interaction  not superconducting

More Related