Erratum: Exciton binding energies in carbon nanotubes from two-photon photoluminescence [Phys. Rev. B.<b>72</b>, 241402(R) (2005)]

Maultzsch, Janina; Pomraenke, R.; Reich, Stéphanie; Chang, Eric K.; Prezzi, Deborah; Ruini, Alice; Molinari, Elisa; Strano, Michael S.; Thomsen, C.; Lienau, Christoph

doi:10.1103/physrevb.74.169901

Cited by 173 publications

(405 citation statements)

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“…We found a strong red shift caused by DNA-wrapping of between 7 and 17 meV depending on the nanotube chirality. In the next step, TENOM was used to resolve PL variations along DNA-wrapped (6,5) and (6,4) nanotubes. Here two distinct emission bands are identified and assigned to emission from DNA-wrapped segments of the nanotube at E DNA and unwrapped segments at E 0 , distinguished by energy shifts of 18 meV for (6,5) and 30 meV for (6,4)-nanotubes, respectively.…”

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“…Figure 2 presents the near-field PL measurement of a DNA-wrapped CoMoCAT (6,5) SWNT spin-coated on mica. Figure 2b represents the integrated intensity from 970 to 1030 nm covering the emission range of (6,5) nanotubes. 7 First, the center emission energies were obtained by fitting the spectra with a single Lorentzian line shape function shown in Figure 2c and d. Apparently, the emission energy varies between 1.259 and 1.241 eV along the nanotube, as indicated by the two red dashed lines in Figure 2c, while the average of all near-field spectra at 1.249 eV coincides with the value from confocal far-field measurements.…”

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Visualizing the Local Optical Response of Semiconducting Carbon Nanotubes to DNA-Wrapping

et al. 2008

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We studied the local optical response of semiconducting single-walled carbon nanotubes to wrapping by DNA segments using high resolution tip-enhanced near-field microscopy. Photoluminescence (PL) near-field images of single nanotubes reveal large DNA-wrapping-induced red shifts of the exciton energy that are two times higher than indicated by spatially averaging confocal microscopy. Near-field PL spectra taken along nanotubes feature two distinct PL bands resulting from DNA-wrapped and unwrapped nanotube segments. The transition between the two energy levels occurs on a length scale smaller than our spatial resolution of about 15 nm.Semiconducting single-walled carbon nanotubes (SWNTs) as photoluminescent quasi-one-dimensional systems have attracted enormous scientific interest and have large potential for various applications in photonics and opto-and nanoelectronics. 1-3 Photoluminescence (PL) of nanotubes results from exciton recombination and occurs in the near-infrared spectral range with emission energies controlled mainly by the nanotube structure (n,m). [4][5][6][7][8] Since nanotubes consist of surface atoms only, the detected emission energy is very sensitive to the nanotube environment, making them promising candidates for sensing applications. 9 At present, the influence of the environment is described by its relative dielectric constant ε influencing exciton binding energies but also renormalizing the band gap through charge carrier screening. 10-14 As a result, the emission energy of nanotubes is modulated by the dielectric constant, which can be expected to be nonuniform along nanotubes, leading to nonuniform emission energies in single nanotube measurements. 8,15,16 The use of DNA for hybridization of carbon nanotube sidewalls has facilitated sorting nanotubes and building chemical sensors. 9,[17][18][19] Single-strand DNA-wrapping introduces DNA segments with finite length, while the details of the secondary DNA structure will be determined by a complex interplay between π-π stacking interactions between DNA bases and nanotube surface as well as electrostatic interactions of the phosphate backbone. [20][21][22] The effect of helical wrapping by the charged DNA backbone was modeled by applying a helical potential causing symmetry breaking of the nanotube electronic structure and small energetic shifts for semiconducting nanotubes (0.01 meV in water). 23,24 It is well-known that DNA-wrapping red-shifts the PL energy depending on the nanotube chirality by several tens of meV compared to the values reported for micelleencapsulated nanotubes in aqueous solution, 7,25,26 which can be attributed to an increasing ε. 14 The surface coverage with DNA segments of finite length is expected to result in a nonuniform dielectric environment along the nanotubes. 25 Limited by diffraction, the PL information collected in confocal microscopy contains the optical response from a nanotube length of about 300 nm, which is far too large to clarify details of individual DNA-nanotube interactions. Tipenhanced n...

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Visualizing the Local Optical Response of Semiconducting Carbon Nanotubes to DNA-Wrapping

et al. 2008

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“…This is a well known phenomenon in biological systems, conjugated polymers, quantum wires, dots, and other lowdimensional systems [11,12,13,14,15], which we now clearly identify in nanotubes. We find that energy transfer is a major non-radiative relaxation channel for large (8,4), (7,6) and (9,4) SWNTs, with excitation matching eh11, eh22,eh33 of (6,5).…”

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“…The investigation of the optical properties of nanotubes is now a most pursued research area [2,3,5,6,7,8,9,10], however this still focuses on individual tubes, in contrast with their natural occurrence in bundles. Furthermore, the luminescence quantum yield of individual SWNTs is very low and this hinders their applications in optoelectronics [3,9,10].…”

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Photoluminescence Spectroscopy of Carbon Nanotube Bundles: Evidence for Exciton Energy Transfer

et al. 2007

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Photoluminescence is commonly used to identify the electronic structure of individual nanotubes. But, nanotubes naturally occur in bundles. Thus, we investigate photoluminescence of nanotube bundles. We show that their complex spectra are simply explained by exciton energy transfer between adjacent tubes, whereby excitation of large gap tubes induces emission from smaller gap ones via Förster interaction between excitons. The consequent relaxation rate is faster than nonradiative recombination, leading to enhanced photoluminescence of acceptor tubes. This fingerprints bundles with different compositions and opens opportunities to optimize them for opto-electronics.

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“…Optical responses of carbon nanotubes are of great interest in fundamental physics and device applications since a small number of exciton states dominate them and, actually, strong excitonic responses are confirmed by experimental and theoretical researches [1,2]. The excitons in semiconducting carbon nanotubes have large binding energies of the order of hundreds of milielectron volts owing to the Coulomb interaction in one-dimensional systems.…”

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Effects of Dynamic Screening on Excitons in Metallic Carbon Nanotubes

Tomio¹,

Suzuura²

2015

Proceedings of the International Symposium “Nanoscience and Quantum Physics 2012” (nanoPHYS’12)

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Excitonic effects and the absorption spectra of metallic carbon nanotubes are studied in an effectivemass scheme by taking dynamic screening into consideration. The result shows that the dynamic screening makes the excitons in metallic carbon nanotubes more stable than the static screening neglecting the retardation in the screening of Coulomb interaction. The dynamic screening effect appears only in the exciton states and it is hardly seen in continuum states.

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Erratum: Exciton binding energies in carbon nanotubes from two-photon photoluminescence [Phys. Rev. B.72, 241402(R) (2005)]

Cited by 173 publications

References 1 publication

Visualizing the Local Optical Response of Semiconducting Carbon Nanotubes to DNA-Wrapping

Visualizing the Local Optical Response of Semiconducting Carbon Nanotubes to DNA-Wrapping

Photoluminescence Spectroscopy of Carbon Nanotube Bundles: Evidence for Exciton Energy Transfer

Effects of Dynamic Screening on Excitons in Metallic Carbon Nanotubes

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