Optical Spectroscopy of Single-Walled Carbon Nanotubes

1. Optical Spectroscopy of Single-Walled Carbon Nanotubes

3. References to Published Papers F. Wang, G. Dukovic, L. E. Brus, and T. F. Heinz, �Time-Resolved Fluorescence in Carbon Nanotubes and Its Implication for Radiative Lifetimes,� Phys. Rev. Lett. 92, 177401 (2004). F. Wang, G. Dukovic, E. Knoesel, L.E. Brus, T.F. Heinz, "Observation of rapid Auger recombination in optically excited semiconducting carbon nanotubes," Phys. Rev. B 70, 241403 (2004) M.Y. Sfeir ,F. Wang ,L.M. Huang ,C.C. Chuang ,J. Hone ,S.P. O'Brien ,T.F. Heinz ,L.E. Brus, "Probing electronic transitions in individual carbon nanotubes by Rayleigh scattering," Science 306 1540-1543 (2004) G. Dukovic, B. E. White, Z. Zhou, F. Wang, S. Jockusch, M.L. Steigerwald, T.F. Heinz, R.A. Friesner, N.J. Turro, L.E. Brus, " Reversible Surface Oxidation and Efficient Luminescence Quenching in Semiconductor Single-Wall Carbon Nanotubes," JACS 126 15269-15276 (2004)

4. Carbon NanotubesSWNT

5. Carbon Nanotubes:Rolled-up Graphene Sheet

6. Electronic Structure

7. Electrical Transport Properties of SWNTs Distinctive metallic and semiconducting transport properties Ballistic transport, Extremely high current carrying capacity

8. Optical Properties Signature of excited states Route to explore carrier dynamics Potential for optoelectronic applications as emitters, detectors, NLO elements with tunable response based on SWNT structure

9. Light Emission from SWNT

11. Fluorescence Spectra

12. Some Outstanding Issues What controls the quantum efficiency What are the non-radiative relaxation channesl How are the rates and pathways of energy relaxation to the band edge What is the nature of the excited states (free carriers or excitons)

13. Time-Resolved Fluorescence by Optical Kerr Gating

14. Time-Resolved Fluorescence

15. Radiative Recombination Lifetime

16. Radiative Recombination Lifetime: Theoretical Prediction

17. Implication of the Radiative Lifetime

18. New Channel with Multiple e-h Pairs

19. Multi-Carrier Interaction: Auger Process(Exciton-Exciton Annihilation)

21. Modeling vs. Experiment

22. Summary: Carrier Dynamics in SWNT

24. pH dependence of SWNT luminescence

25. SWNT Oxide: Experimental Observations

26. Direct observation of oxygen desorption

27. SWNT Oxide Structure

28. Hole-Induced Fluorescence Quenching

29. Summary: Sidewall Oxide � Optical Properties

30. Challenge: Studying Individual Nanotubes

31. Optical Spectroscopy of Single Nanotubes

32. I: Supercontinuum Radiation

33. Microstructured Optical Fiber

34. II: Suspended Carbon Nanotubes

35. CVD Growth of SWNTs across Slit Sample

36. Two Types of Rayleigh Spectra from Individual Nanotubes

37. Rayleigh Scattering from Nanotubes

38. Rayleigh Scattering from Nanotubes

39. Understanding the Scattering Spectra

40. Rayleigh Scattering from Nanotubes

41. Understanding the Scattering Spectra

42. Polarization Dependence of The Rayleigh Scattering

43. Polarization Perpendicular to the SWNT: Depolarization Effect

44. Scattering Spectra along the Nanotube: Single Tube

45. Scattering Spectra along the Nanotube: Single Tube to Bundle of Two SWNTs

46. Correlated Raman and Rayleigh Scatterings from the Same Nanotube

47. Summary: Rayleigh Scattering

48. Overall Summary