Raman spectroscopy and mapping, coupled to molecular labelling, is used to analyse and monitor the first stage of carbon nanotube functionalization, i.e. their oxidation, which is usually performed to increase the number of surface carboxylic groups, allowing both a better dispersion in solution and the further attachment of biomolecules. Since the abundance of such surface groups is critical for the final application, it is important to develop a reliable but simple and fast method to investigate their presence on the tube walls. The presented data demonstrate the correlation between the presence and intensity of the Raman peak ascribed to the labelling molecule and the production of COOH groups on the nanotube walls. Between the analysed carbon nanotubes related spectral parameters, the G0 Raman peak position appears to be the most sensitive one to determine the degree of single walled carbon nanotube labelling, which directly depends on the number of COOH groups available for molecular attachment, i.e. on the efficiency of the oxidation treatment. The presented results demonstrate that it is possible to directly use the Raman signal of the THA labelling molecule for the COOH groups determination. In particular, the labelling is extremely useful to overcome the limitations of Raman spectroscopy alone in determining the degree of oxidation, so that such a method can be applied to study the oxidation itself, with particular reference to its efficiency and to the analysis of the presence of carbonaceous impurities (fulvic acids residues) in acid treated SWCNT samples. We are presently working in this direction, also applying the THA-method to monitoring different oxidation techniques, such as microwave and plasma treatments.

Raman analysis and mapping for the determination of COOH groups on oxidized single walled carbon nanotubes

MUSSI, VALENTINA;VALBUSA, UGO
2010-01-01

Abstract

Raman spectroscopy and mapping, coupled to molecular labelling, is used to analyse and monitor the first stage of carbon nanotube functionalization, i.e. their oxidation, which is usually performed to increase the number of surface carboxylic groups, allowing both a better dispersion in solution and the further attachment of biomolecules. Since the abundance of such surface groups is critical for the final application, it is important to develop a reliable but simple and fast method to investigate their presence on the tube walls. The presented data demonstrate the correlation between the presence and intensity of the Raman peak ascribed to the labelling molecule and the production of COOH groups on the nanotube walls. Between the analysed carbon nanotubes related spectral parameters, the G0 Raman peak position appears to be the most sensitive one to determine the degree of single walled carbon nanotube labelling, which directly depends on the number of COOH groups available for molecular attachment, i.e. on the efficiency of the oxidation treatment. The presented results demonstrate that it is possible to directly use the Raman signal of the THA labelling molecule for the COOH groups determination. In particular, the labelling is extremely useful to overcome the limitations of Raman spectroscopy alone in determining the degree of oxidation, so that such a method can be applied to study the oxidation itself, with particular reference to its efficiency and to the analysis of the presence of carbonaceous impurities (fulvic acids residues) in acid treated SWCNT samples. We are presently working in this direction, also applying the THA-method to monitoring different oxidation techniques, such as microwave and plasma treatments.
File in questo prodotto:
Non ci sono file associati a questo prodotto.

I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.

Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11567/286512
Citazioni
  • ???jsp.display-item.citation.pmc??? ND
  • Scopus ND
  • ???jsp.display-item.citation.isi??? ND
social impact