Comparison of the Quality of Aqueous Dispersions of Single Wall Carbon Nanotubes Using Surfactants and Biomolecules

Haggenmueller, Reto; Rahatekar, Sameer S.; Fagan, Jeffrey; Chun, Jaehun; Becker, Matthew L.; Naik, Rajesh R.; Krauss, Todd D.; Carlson, Lisa J.; Kadla, John F.; Trulove, Paul C.; Fox, Douglas M.; Delong, Hugh C.; Fang, Zhichao; Kelley, Shana O.; Gilman, Jeffrey W.

doi:10.1021/la703008r

Cited by 225 publications

(281 citation statements)

References 43 publications

(98 reference statements)

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“…160 In particular, the large variation in Stokes shifts highlights the importance of the local environment surrounding the SWNT. 149 For most surfactants, the relatively small Stokes shift was well within the range of accepted literature values (~45 cm -1 ); 87 the Stokes shift observed for CAS was larger than expected (125.1 cm -1 ). In all spectra, corresponding peaks in the absorption and fluorescence spectra (i.e., that arose from the same SWNT structures) exhibited only small Stokes shifts, indicating a set of chromophores with minimal differences in the amount of electron-phonon coupling occurring in the ground and excited states.…”

Section: Recommended Swnt Dispersing Agentssupporting

confidence: 76%

“…For example, complete luminescence quenching has been observed when SWNTs directly contact metallic nanotubes in bundles 71 and when they touch some substrates such as silicon; however, it is important to note that these substrates were also coated with catalyst particles and residual carbon deposits from SWNT CVD syntheses. 154,189 Attenuation of nanotube fluorescence also accompanies dispersal in polar solvents, 218 encapsulation in certain surfactant systems, 149 protonation at low pH, 167 and shortening of the nanotube length. 212 In addition, the presence of defect sites, impurities, and oxygen is expected to decrease the QY via hole doping, which effectively removes an electron from the valence band and provides a trap for the excited state.…”

Section: Motivationmentioning

confidence: 99%

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Photophysics of Individual Single-Walled Carbon Nanotubes

2008

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Single-walled carbon nanotubes (SWNTs) are cylindrical graphitic molecules that have remained at the forefront of nanomaterials research since 1991, largely due to their exceptional and unusual mechanical, electrical, and optical properties. The motivation for understanding how nanotubes interact with light (i.e., SWNT photophysics) is both fundamental and applied. Individual nanotubes may someday be used as superior near-infrared fluorophores, biological tags and sensors, and components for ultrahigh-speed optical communications systems. Establishing an understanding of basic nanotube photophysics is intrinsically significant and should enable the rapid development of such innovations. Unlike conventional molecules, carbon nanotubes are synthesized as heterogeneous samples, composed of molecules with different diameters, chiralities, and lengths. Because a nanotube can be either metallic or semiconducting depending on its particular molecular structure, SWNT samples are also mixtures of conductors and semiconductors. Early progress in understanding the optical characteristics of SWNTs was limited because nanotubes aggregate when synthesized, causing a mixing of the energy states of different nanotube structures. Recently, significant improvements in sample preparation have made it possible to isolate individual nanotubes, enabling many advances in characterizing their optical properties. In this Account, single-molecule confocal microscopy and spectroscopy were implemented to study the fluorescence from individual nanotubes. Single-molecule measurements naturally circumvent the difficulties associated with SWNT sample inhomogeneities. Intrinsic SWNT photoluminescence has a simple narrow Lorentzian line shape and a polarization dependence, as expected for a one-dimensional system. Although the local environment heavily influences the optical transition wavelength and intensity, single nanotubes are exceptionally photostable. In fact, they have the unique characteristic that their single molecule fluorescence intensity remains constant over time; SWNTs do not “blink” or photobleach under ambient conditions. In addition, transient absorption spectroscopy was used to examine the relaxation dynamics of photoexcited nanotubes and to elucidate the nature of the SWNT excited state. For metallic SWNTs, very fast initial recovery times (300–500 fs) corresponded to excited-state relaxation. For semiconducting SWNTs, an additional slower decay component was observed (50–100 ps) that corresponded to electron–hole recombination. As the excitation intensity was increased, multiple electron–hole pairs were generated in the SWNT; however, these e−h pairs annihilated each other completely in under 3 ps. Studying the dynamics of this annihilation process revealed the lifetimes for one, two, and three e−h pairs, which further confirmed that the photoexcitation of SWNTs produces not free electrons but rather one-dimensional bound electron–hole pairs (i.e., excitons). In summary, nanotube photophysics is a rapidly developing area o...

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Section: Recommended Swnt Dispersing Agentssupporting

confidence: 76%

Section: Motivationmentioning

confidence: 99%

Photophysics of Individual Single-Walled Carbon Nanotubes

2008

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“…Thus it is possible to sort these SWCNTs using density gradient ultracentrifugation (DGU) [18][19][20]. The dispersion mechanism has been explored and results indicate that the adsorption of surfactants on the surface of SWCNTs forms stronger p-p stacking interactions than those between the SWCNTs [21]. For the non-covalent functionalization of SWCNTs, the useful agents include surfactants, polymers, as well as biomolecules such as DNA [5,[22][23][24][25].…”

Section: Introductionmentioning

confidence: 99%

Optimizing sonication parameters for dispersion of single-walled carbon nanotubes

Yu¹,

Hermann²,

Schulz³

et al. 2012

Chemical Physics

116

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“…Other compounds used for the noncovalent functionalization and dispersing of CNT include: ionic liquids (ILs) -which form bucky gels, polymers -especially those with aromatic rings in their structure [24], other compounds with an aromatic ring [25] (for example ammonium salts containing pyrene rings [26]) and or deoxycholic acid sodium salts [27].…”

Section: Methods Of Dispersing Carbon Nanotubes -The Search For Optimmentioning

confidence: 99%

Congo Red Interactions with Single-Walled Carbon Nanotubes

Jagusiak

Piekarska

Chłopaś

et al. 2017

Self-Assembled Molecules – New Kind of Protein Ligands

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A new method of dispersion of single-wall carbon nanotubes (SWNT) in aqueous solution using supramolecular compounds is proposed in this chapter. The described system consists of SWNT overlaid by Congo red. SWNT are formed from a rolled layer of graphene, providing a large surface area for binding compounds with planar, aromatic structures (including drugs). Congo red is able to associate with proteins in the form of supramolecular, ribbon-like structures, and may bind various drugs by intercalation.The study reveals strong interactions between Congo red and the surface of SWNT. The authors' aim was to explain the mechanism driving this interaction. Spectral analysis of the SWNT-CR complex, effects of sonication on CR binding, microscopic imaging and molecular modelling analyses are all discussed. Results indicate that binding of supramolecular Congo red to the surface of nanotubes is based on face-to-face stacking. Having attached itself to the surface of a nanotube, a dye molecule may attract other similarly oriented molecules, giving rise to a protruding supramolecular appendage. This explains the high affinity of CR for nanotubes and the resulting system's capability to bind drugs.Analysis of complexes formed by SWNT-CR with the model drug (DOX) and with other planar compounds (EB, TY) indicates that it may be possible to construct complexes capable of binding multiple compounds simultaneously.

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Comparison of the Quality of Aqueous Dispersions of Single Wall Carbon Nanotubes Using Surfactants and Biomolecules

Cited by 225 publications

References 43 publications

Photophysics of Individual Single-Walled Carbon Nanotubes

Photophysics of Individual Single-Walled Carbon Nanotubes

Optimizing sonication parameters for dispersion of single-walled carbon nanotubes

Congo Red Interactions with Single-Walled Carbon Nanotubes

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