posted on 2022-04-14, 14:06authored byFinn L. Sebastian, Nicolas F. Zorn, Simon Settele, Sebastian Lindenthal, Felix J. Berger, Christoph Bendel, Han Li, Benjamin S. Flavel, Jana Zaumseil
The functionalization
of semiconducting single-wall carbon nanotubes
(SWCNTs) with luminescent sp3 defects creates red-shifted
emission features in the near-infrared and boosts their photoluminescence
quantum yields (PLQYs). While multiple synthetic routes for the selective
introduction of sp3 defects have been developed, a convenient
metric to precisely quantify the number of defects on a SWCNT lattice
is not available. Here, we present a direct and simple quantification
protocol based on a linear correlation of the integrated Raman D/G+ signal ratios and defect densities as extracted from PLQY
measurements. Corroborated by a statistical analysis of single-nanotube
emission spectra at cryogenic temperature, this method enables the
quantitative evaluation of sp3 defect densities in (6,5)
SWCNTs with an error of ±3 defects per micrometer and the determination
of oscillator strengths for different defect types. The developed
protocol requires only standard Raman spectroscopy and is independent
of the defect configuration, dispersion solvent, and nanotube length.