Calculation of the vibrational frequencies of carbon clusters and fullerenes with empirical potentials

Do, Hainam; Besley, Nicholas A.

doi:10.1039/c4cp05424e

Cited by 13 publications

(7 citation statements)

References 62 publications

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“…Semiempirical methods have recently been shown to correspond fairly well with experiments. 46,47 The vibrational density of states (VDOS) can well be used to determine many chemical and physical properties of carbon nanotubes. Besides studying chirality and defects, the VDOS can also be used to calculate thermal conductivity.…”

Section: Introductionmentioning

confidence: 99%

Structural characterization of carbon nanotubes via the vibrational density of states

Pool

Jain

Barkema

2017

Carbon

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The electrical and chemical properties of carbon nanotubes vary significantly with different chirality and diameter, making the experimental determination of these structural properties important. Here, we show that the vibrational density of states (VDOS) contains information on the structure of carbon nanotubes, particularly at low frequencies. We show that the diameter and chirality of the nanotubes can be determined from the characteristic low frequency L and L modes in the VDOS. For zigzag nanotubes, the L peak splits into two peaks giving rise to another low energy L peak. The significant changes in the frequencies and relative intensities of these peaks open up a route to distinguish among structurally different nanotubes. A close study of different orientations of Stone-Wales defects with varying defect density reveals that different structural defects also leave distinct fingerprints in the VDOS, particularly in the L and L modes. With our results, more structural information can be obtained from experiments which can directly measure the VDOS, such as inelastic electron and inelastic neutron spectroscopy.

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Section: Introductionmentioning

confidence: 99%

Structural characterization of carbon nanotubes via the vibrational density of states

Pool

Jain

Barkema

2017

Carbon

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“…We have assumed those multiplicities for the calculations. The calculated vibrational frequencies are listed in Table 1, together with the experimental values, given in [30]. While the lowest-energy modes are well reproduced by the calculations, some deviations are seen for the higher frequency modes.…”

Section: Level Densitiesmentioning

confidence: 83%

Vibrational angular momentum level densities of linear molecules

Hansen,

Ferrari

2020

Preprint

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While linear molecules in their vibrational ground state cannot carry angular momentum around their symmetry axis, the presence of vibrational excitations can induce deformations away from linearity and therefore also allow angular momentum along the molecular axis. In this work, a recurrence relation is established for the calculation of the vibrational level densities (densities of states) of linear molecules, specified with respect to both energy and angular momentum. The relation is applied to the carbon clusters of sizes n = 4, 6, 7 as a case study.

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“…Atac et al suggested that the C�O difference between DFT and experimental can go up to 35 cm −1 differences [33]. At the same time, Do et al found the difference between the theory and the experimental goes up to 58 cm −1 for a large molecule like C 60 fullerenes (even though the molecule is highly symmetric and has no functional group other than C�C) [34].…”

Section: Discussionmentioning

confidence: 99%

Experimental and Density Functional Theory Characteristics of Ibrutinib, a Bruton’s Kinase Inhibitor Approved for Leukemia Treatment

Ismail

2021

Journal of Spectroscopy

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Ibrutinib, a Bruton’s tyrosine kinase that plays an essential role in the B-cell development and cancer cells, has been recently approved to treat chronic, lymphocytic, and other types of leukemia. This study focused on investigating ibrutinib by its electronic transitions, vibrational frequencies, and electrospray mass spectra. The experimental peaks for electronic spectrum were found at 248.0 and 281.0 nm, whereas the νC = 0 stretching frequency was found at 1652.4 and 1639.19 cm−1. These experimental properties were compared with the corresponding theoretical calculations in which density functional theory was applied. The optimized structure was obtained with the calculations using a hybrid function (B3LYP) and high-level basis sets [6-311G++(d,p)]. Most of the calculated vibrational frequencies showed a relatively good agreement with the experimental ones. The electronic transitions of ibrutinib calculated using time-dependent DFT method were performed at two different solvation methods: PCM and SMD. The mass spectrum of ibrutinib, its fragments, and its isotopic pattern agreed well with the expected spectra.

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Calculation of the vibrational frequencies of carbon clusters and fullerenes with empirical potentials

Cited by 13 publications

References 62 publications

Structural characterization of carbon nanotubes via the vibrational density of states

Structural characterization of carbon nanotubes via the vibrational density of states

Vibrational angular momentum level densities of linear molecules

Experimental and Density Functional Theory Characteristics of Ibrutinib, a Bruton’s Kinase Inhibitor Approved for Leukemia Treatment

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