Bea Botka scite author profile

Specific and tunable modification to the optical properties of single-wall carbon nanotubes (SWCNTs) is demonstrated through direct encapsulation into the nanotube interior of guest molecules with widely varying static dielectric constants. Filled through simple ingestion of the guest molecule, each SWCNT population is demonstrated to display a robust modification to absorbance, fluorescence, and Raman spectra. Over 30 distinct compounds, covering static dielectric constants from 1.8 to 109, are inserted in large diameter SWCNTs (d = 1.104−1.524 nm) and more than 10 compounds in small diameter SWCNTs (d = 0.747−1.153 nm), demonstrating that the general effect of filler dielectric on the nanotube optical properties is a monotonic energy reduction (red-shifting) of the optical transitions with increased magnitude of the dielectric constant. Systematic fitting of the twodimensional fluorescence−excitation and Raman spectra additionally enables determination of the critical filling diameter for each molecule and distinguishing of overall trends from specific guest−host interactions. Comparisons to predictions from existing theory are presented, and specific guest molecule/SWCNT chirality combinations that disobey the general trend and theory are identified. A general increase of the fluorescence intensity and line narrowing is observed for low dielectric constants, with long linear alkane filled SWCNTs exhibiting emission intensities approaching those of empty SWCNTs. These results demonstrate an exploitable modulation in the optical properties of SWCNTs and provide a foundation for examining higher-order effects, such as due to nonbulk-like molecule stacking, in host−guest interactions in well-controlled nanopore size materials.

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Interactions and Chemical Transformations of Coronene Inside and Outside Carbon Nanotubes

Botka

Füstös

Tóháti

et al. 2013

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Investigation of fullerene encapsulation in carbon nanotubes using a complex approach based on vibrational spectroscopy

Botos

Khlobystov

Botka

et al. 2010

Physica Status Solidi (b)

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For carbon nanotubes filled with fullerenes (''peapods''), it is a key issue to find an analytical method that distinguishes the molecules inside the nanotube from those adsorbed on its surface. High-resolution transmission electron microscopy (HRTEM) detects both encapsulated and adsorbed molecules which are large enough (e.g., fullerenes), but being a localprobe method, it cannot be applied to large amounts of sample. In Raman spectroscopy, the empirical rules for line shifts and splitting are nanotube-type dependent and often ambiguous. We prepared C 60 peapods by nano-extraction using supercritical CO 2 as a solvent, and subsequently removed the adsorbed fullerene molecules by washing the samples. We analyzed the samples by the combination of HRTEM, Raman, and midinfrared attenuated total reflectance (MIR-ATR) spectroscopy. Although the TEM images proved that the nanotubes were filled with fullerenes, we did not observe any shift in the fullerene's A g (2) Raman mode compared to C 60 crystals. ATR spectra, on the other hand, were found to detect only the adsorbed molecules. Therefore, the combination of the two methods provide good basis for determining the success of nanotube filling by spectroscopy alone.

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Low‐temperature encapsulation of coronene in carbon nanotubes

Botka

Füstös

Klupp

et al. 2012

Physica Status Solidi (b)

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Coronene was encapsulated in single-walled carbon nanotubes (SWNT) by vapor-phase filling at high (450 8C) and low (385 8C) temperature and by nanoextraction from supercritical carbon dioxide. The presence of coronene inside the tubes was demonstrated indirectly via the formation of double-walled nanotubes (DWNT). To this end several subsequent annealing steps were applied and monitored by Raman spectroscopy. Our results show that the encapsulation is successful with all three methods. However, high-temperature vapor filling produces adsorbed dicoronylene, the dimerized form of coronene, as a side reaction. In order to avoid dicoronylene contamination, we suggest to use low-temperature methods for the production of coronene-filled carbon nanotubes.Coronene (top) and dicoronylene (bottom) molecules.

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Bea Botka

Optical Property Tuning of Single-Wall Carbon Nanotubes by Endohedral Encapsulation of a Wide Variety of Dielectric Molecules

Interactions and Chemical Transformations of Coronene Inside and Outside Carbon Nanotubes

Investigation of fullerene encapsulation in carbon nanotubes using a complex approach based on vibrational spectroscopy

Low‐temperature encapsulation of coronene in carbon nanotubes

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