Hostname: page-component-586b7cd67f-r5fsc Total loading time: 0 Render date: 2024-11-23T15:51:33.955Z Has data issue: false hasContentIssue false
  • English
  • Français

Single Walled Carbon Nanotube Analysis by Photoluminescence and Raman Microscopy: Rapid, Robust Acquisition and Simulation of Quantum and Chiral Maps to Ease Structural Assignments

Published online by Cambridge University Press:  01 February 2011

Adam Matthew Gilmore ,
Fran Adar ,
Eunah Lee ,
Ray Kaminski  and
Andrew Whitley
Adam Matthew Gilmore
Affiliation:
[email protected], HORIBA Jobin Yvon, Fluorescence, 3880 Park Ave., Edison, NJ, 08820, United States, 732-494-8660 x135, 732-549-5157
Fran Adar
Affiliation:
[email protected], HORIBA Jobin Yvon, Molecular and Microanalysis Division, 3880 Park Ave, Edison, NJ, 08820, United States
Eunah Lee
Affiliation:
[email protected], HORIBA Jobin Yvon, Molecular and Microanalysis Division, 3880 Park Ave, Edison, NJ, 08820, United States
Ray Kaminski
Affiliation:
[email protected], HORIBA Jobin Yvon, Molecular and Microanalysis Division, 3880 Park Ave, Edison, NJ, 08820, United States
Andrew Whitley
Affiliation:
[email protected], HORIBA Jobin Yvon, Molecular and Microanalysis Division, 3880 Park Ave, Edison, NJ, 08820, United States
Get access

Abstract

This paper describes improved methods for both data acquisition and analysis that are pertinent to interpreting the structural composition of single-walled carbon nanotube (SWNT) mixtures and suspensions.

Rapid data acquisition of photoluminescence is made possible with a specially configured spectrofluorometer which uses a liquid nitrogen-cooled InGaAs array detector, imaging spectrograph, excitation reference photodiode and tunable xenon excitation source to collect seamless, instrument-corrected, excitation-emission quantum maps. The preferred instrument configuration with the InGaAs array can generate a quantum map with both high S/N levels and spectral resolution in only seconds to minutes; previous single-channel InGaAs photodiode and photomultiplier detector measurements took hours to days. The standard spectral range for excitation and emission is from 250 nm to 1700 nm with an option to extend to 2200 nm. Robust analysis of the quantum maps is facilitated by a custom global analysis program (US Patent Pending) which incorporates a powerful ‘double-convolution integral’ DCI algorithm to simultaneously model the excitation and emission spectral bands for each SWNT species. The patented DCI algorithm reduces the number of free fitting parameters for the spectral simulation by up to a factor of 1000 compared to conventional 2 D spectral simulators. The global analysis yields quantitative information on the chirality and diameter parameters of SWNT species in a given mixture. Together the acquisition hardware and analysis software constitute significant developments with respect to enhanced sensitivity and statistical significance for quantifying the components of complex SWNT mixtures.

Raman maps of SWNT's were collected from dispersions plated onto substrates such as silicon plates using multiple excitation wavelengths. Identification of the chirality of the tubes was made using the Kataura plot. In many instances single lines in the radial breathing mode region were recorded indicating the presence of a single tube. The implication for this observation is that there is more than adequate sensitivity to detect and identify single-walled tubes. More recently Raman excitation on an AFM using a gold-coated tip to induce surface enhancement has been achieved. In this configuration it will be possible to map the topology of the tubes using detailed information on their structural composition.

Keywords

nanostructureRaman spectroscopyphotoemission
Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 963: Symposium Q – Nanowires and Carbon Nanotubes – Science and Applications , 2006 , 0963-Q19-02
Copyright
Copyright © Materials Research Society 2007

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

1. Heller, D.A., Jeng, E.S., Yeung, T-K, Martinez, B.M., Moll, A.E., Gastala, J.B., Strano, M.S., Science, 311, 508.511, (2006).Google Scholar
2. Zorman, B., Ramakrishna, M.V., Friesner, R.A., J. Phys. Chem., 99, 7649.7653, (1995).Google Scholar
3. Steckel, J.S., Zimmer, J.P., Coe-Sullivan, S., Stott, N.E., Bulovic, V., Bawendi, M.G., Angew. Chem. Inter. Ed., 43, 2154.2158, (2004).Google Scholar
4. Bachilo, S.M., Strano, M.S., Kittrell, C., Huage, R.H., Smalley, R.E., Weisman, R.B., Science, 298, 23361.2366, (2002).Google Scholar
5. O'Connell, M.J., Bachilo, S.M., Huffman, C.B., Moore, V.C., Strano, M.S., Haroz, E. H., Rialon, K.L., Boul, P. J., Noon, W.H., Kittrell, C., Ma, J., Hauge, R. H., Weisman, R. B., Smalley, R.E. Science, 297, 593.596, (2002).Google Scholar
6. Thomsen, C. and Reich, S., Phys. Rev. Lett., 85, 5214 (2000)10.1103/PhysRevLett.85.5214Google Scholar
7. Dresselhaus, M.S., Dresselhaus, G., Pimenta, M.A. and Eklund, P.C., Analytical Applications of Raman Spectroscopy, Chap. 9, pp367434.Google Scholar
8. Dresselhaus, and Eklund, , Adv. Physics 49, 705814, (2000)Google Scholar
9. Dresselhaus, M.S., Jorio, A., Souza Filho, A.G., Dresselhaus, G., R. Saito Physica B 323 15-20, (2002).Google Scholar
10. Resasco, D.E., Alvarez, W.E., Pompeo, F., Balzano, L., Herrera, J.E., Kitiyanan, B., Borgna, A., J. Nanoparticle Res., 4, 131.136, (2002).Google Scholar
11. Bachilo, S.M., Balzano, L., Herrera, J.E., Pompeo, F., Resasco, D.E., Weisman, R.B., J. Am.Chem. Soc., 125, 11186.11187, (2003).Google Scholar
12. Rao, , Dresselhaus, et al., Science 10, 275, 187 (1997).Google Scholar
13. Hadjiev, V.G., Arepalli, S., Nikolaev, P., Jandl, S. and Yowel, L., Nanotechnology 15, 562567 (2004)Google Scholar