Electron energy-loss spectroscopy studies of single wall carbon nanotubes

Carbon

Volumn 37, Issue 5, 1999, Pages 733-738

  Knupfer, M ^a   Pichler, T ^a   Golden, M S ^a   Fink, J ^a   Rinzler, A ^b   Smalley, R E ^b  

^a IFW DRESDEN   (Germany)

^b RICE UNIVERSITY   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

CARBON; ELECTRON ENERGY LOSS SPECTROSCOPY; ELECTRON TRANSITIONS; ELECTRONIC DENSITY OF STATES; ELECTRONIC PROPERTIES; OPTICAL PROPERTIES; SEMICONDUCTOR MATERIALS;

SINGLE WALL CARBON NANOTUBES;

NANOTUBES;

EID: 0032679478     PISSN: 00086223     EISSN: None     Source Type: Journal    
DOI: 10.1016/S0008-6223(98)00263-2     Document Type: Article

References (37)

1. Saito S. Science. 278:1997;77.
2. Chico L., Crespi V.H., Benedict L.X., Louie S.G., Cohen M.L. Phys Rev Lett. 76:1996;971.
3. Wong E.W., Sheehan P.E., Lieber C.M. Science. 277:1997;1971.
4. Mimitmire J.W., Dunlop B.I., White C.T. Phys Rev Lett. 68:1992;631.
5. Hamada N., Sawada S.I., Oshiyama A. Phys Rev Lett. 68:1992;1579.
6. Dresselhaus MS, Dresselhaus G, Eklund PC. Science of Fullerenes and Carbon Nanotubes. San Diego: Academic Press, 1996.
7. Tans S.J., Devoret M.H., Dai H.J., Thess A., Smalley R.E.et al. Nature. 386:1997;474.
8. Wildör J.W.G., Venema L.C., Rinzler A.G., Smalley R.E., Dekker C. Nature. 391:1998;59.
9. Kuzuo R., Terauchi M., Tanaka M. Jpn J Appl Phys. 31:1992;L1484.
10. Ajayan P.M., Ijima S., Ichihashi T. Phys Rev B. 49:1994;2882.
11. Bursill L.A., Stadelmann P.A., Peng J.L., Prawer S. Phys Rev B. 49:1994;2882.
12. Kuzuo R., Terauchi M., Tanaka M., Saito Y. Jpn J Appl Phys. 33:1994;L1316.
13. Petit P., Jouguelet E., Fischer J.E., Rinzler A.G., Smalley R.E. Phys Rev B. 56:1997;9275.
14. Rao A.M., Richter E., Bandon S., Chase B., Eklund P.C. Science. 275:1997;187.
15. Pichler T., Knupfer M., Golden M.S., Fink J., Rinzler A.et al. Phys Rev Lett. 80:1998;4729.
16. Rao A.M., Ekland S., Bandon S., Thess A., Smalley R.E. Nature. 388:1997;257.
17. Lee R.S., Kim H.J., Fischer J.E., Thess A., Smalley R.E. Nature. 388:1997;255.
18. Thess A., Lee R., Nikolaev P., Dai H., Petit A.et al. Science. 273:1996;483.
19. Rinzler A.G., Liu J., Dai H., Nikolaev P., Huffman C.B.et al. Appl. Phys A. 67:1998;29.
20. Fink J. Adv Electron Electron Phys 1989;75:121.
21. Batson P.E. Phys Rev B. 48:1993;2608.
22. Ma Y., Skytt P., Wassdahl N., Glans P., Mariani D.C.et al. Phys Rev Lett. 71:1993;3725.
23. Mele E.J., Ritsko J.J. Phys Rev Lett. 43:1979;68.
24. Brühwiler P., Maxwell A.J., Puglia C., Nilsson A., Anderson S.et al. Phys Rev Lett. 74:1995;614.
25. van Veenendaal M., Carra P. Phys Rev Lett. 78:1997;2839.
26. Shirley E.L. Phys Rev Lett. 80:1998;794.
27. Golden MS, Pichler T, Knupfer M, Fink J, Rinzler AG, Smalley RE, In: Kuzmany H, Roth S, Fink J, Mehring M, editors. Proceedings of the International Winterschooh on Electronic Properties of Novel Materials 1998, Kirchberg, Tirol, 1998, in press.
28. Lucas A.A., Henrad L., Lambin Ph. Phys Rev B. 49:1994;2888.
29. Lin M.F., Shiung K.W.K. Phys Rev B. 50:1994;17744.
30. Lin M.F., Chuu D.S., Huang C.S., Lin Y.K., Shung KWK Phys Rev B. 53:1996;15493.
31. Romberg H., Sohmen E., Merkel M., Knupfer M., Alexander M.et al. Synthetic Metals. 55 56 57:1993;3038.
32. -1.
33. Fink J., Leising G. Phys Rev B. 34:1986;5320.
34. -1), which is arrived at from an average of the values for graphite in the plane [35] and perpendicular to the plane. It is important to note, however, that the energy positions of the interband transitions in the optical conductivity remain essentially unchanged if a metallic extrapolation to zero energy is assumed (data not shown).
35. Zeppenfeld K. Z Phys. 243:1971;229.
36. Ritsko J.J., Mele E.J. Phys Rev B. 21:1980;730.
37. Sohmen E., Fink J. Phys Rev B. 47(14):1993;532.