Vibrational Infrared and Raman Spectra of Non-Metals

Bilz, H.; Strauch, D.; Wehner, R.K.

doi:10.1007/978-3-642-46433-1_1

Cited by 14 publications

(9 citation statements)

References 1,127 publications

(933 reference statements)

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“…The Raman intensities can be calculated within the framework of the nonresonant bond polarizability model [27]. The basic assumption of the bond polarizability model is that the optical dielectric susceptibility of the material or molecule can be decomposed into individual contributions, arising only from the polarizability α ij b of bonds b between nearest neighbor atoms.…”

Section: The Bond Polarizability Modelmentioning

confidence: 99%

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Structural and Vibrational Properties of C60 and C70 Fullerenes Encapsulating Carbon Nanotubes

Chadli¹,

Fergani²,

Rahmani³

2018

Fullerenes and Relative Materials - Properties and Applications

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Carbon nanotubes (CNTs) can encapsulate small and large molecules, including C 60 and C 70 fullerenes (so-called carbon peapods). The challenge for nanotechnology is to achieve perfect control of nanoscale-related properties, which requires correlating the parameters of synthesis process with the resulting nanostructure. For that purpose, note every conventional characterization technique is suitable, but Raman spectroscopy has already proven to be. First, the different possible configurations of C 60 and C 70 molecules inside CNTs are reviewed. Therefore, the following changes of properties of the empty nanotubes, such as phonon modes, induced by the C 60 and C 70 filling inside nanotube are presented. We also briefly review the concept of Raman spectroscopy technique that provides information on phonon modes in carbon nanopeapods. The dependencies of the Raman spectrum as a function of nanotube diameter and chirality, fullerene molecules configuration and the filling level are identified and discussed. The experimental Raman spectra of fullerenes and fullerenes peapods are discussed in the light of theoretical calculation results. Finally, the variation of the average intensity ratio between C 60 and C 70 Raman-active modes and the nanotube ones, as a function of the concentration molecules, are analyzed, and a general good agreement is found between calculations and measurements.

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Section: The Bond Polarizability Modelmentioning

confidence: 99%

“…n , are linked to the Raman susceptibility of modes (see [27] for the detailed formalism) and are given by:…”

Section: The Bond Polarizability Modelmentioning

confidence: 99%

Structural and Vibrational Properties of C60 and C70 Fullerenes Encapsulating Carbon Nanotubes

Chadli¹,

Fergani²,

Rahmani³

2018

Fullerenes and Relative Materials - Properties and Applications

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“…Explicit expressions for the contributions of these diagrams are given in Ref. 76 ͓apart from ͑f͒ which may be easily evaluated following the rules given therein͔͒. In the temperature range where the infrared absorption experiments have been carried out, the thermal occupation number of the stretching mode is negligibly small.…”

Section: Intrinsic Linewidthmentioning

confidence: 99%

Anharmonic adlayer vibrations on the Si(111):H surface

Honke

Jakob²,

Chabal³

et al. 1999

Phys. Rev. B

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Using infrared absorption spectroscopy, the frequency and linewidth of the H-stretching vibration on the Si͑111͒:H-͑1ϫ1͒ surface has been measured over a temperature range of 14-350 K. An ab initio calculation of the temperature dependence of the anharmonic frequency shift and the intrinsic linewidth of this mode has been carried out, which fully accounts for the quantum nature of the atomic vibrations by using interacting phonon theory. The theoretical results show that at temperatures greater than 200 K, both line shift and linewidth of the stretching mode are primarily due to strong anharmonic coupling to the bending modes, which suffer decay into substrate modes via cubic anharmonicity. At low temperatures, direct coupling to various phonon modes of the substrate dominates the temperature dependence of the line shift. In addition, predictions are made for the frequency shift due to zero-point motion of the atoms. A strong sensitivity of the frequency on the shape of the Si-H potential has been found that makes quantitative predictions of the influence of zero-point motion very difficult. As a byproduct, the temperature dependence of the interatomic distances near the surface has been obtained and a decrease of the H-Si distance with increasing temperature is predicted.

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“…Experiments on molecular overtone and combination bands by means of sensitive absorption, thermal lensing, and photoacoustic spectroscopy, particularly involving X-H vibrations, have been interpreted successfully in terms of normal modes for low-lying vibrational states and local modes for high-lying states. In condensed matter lattices, vibrational energy localization can be produced by lattice irregularities, and such defect-induced localized modes, which appear above the plane wave spectrum, in the frequency gaps between the plane wave branches, or in the acoustic spectrum, have been studied in great detail both theoretically [8][9][10][11][12] and experimentally [13][14][15]. For nonlinear atomic lattices, the study of localized vibrational energy has a much shorter history.…”

Section: Introductionmentioning

confidence: 99%

Experimental and numerical exploration of intrinsic localized modes in an atomic lattice

Satō

Sievers

2009

J Biol Phys

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This review focuses attention on the experimental studies of intrinsic localized modes (ILMs) produced in driven atomic lattices. Production methods involve the application of modulational instability under carefully controlled conditions. One experimental approach is to drive the atomic lattice far from equilibrium to produce ILMs, the second is to apply a driver of only modest strength but nearby in frequency to a plane wave mode so that a slow transformation from large amplitude standing waves to ILMs takes place. Since, in either case, the number of ILMs produced is small, the experimental observation tool appropriate for this task is four-wave mixing. This nonlinear detection technique makes use of the nonlinearity associated with an ILM to enhance its signal over that produced by the more numerous, but linear, spin waves. The final topic deals with numerical simulations of a nonlinear nanoscale atomic lattice where the new feature is running ILMs.

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Vibrational Infrared and Raman Spectra of Non-Metals

Cited by 14 publications

References 1,127 publications

Structural and Vibrational Properties of C60 and C70 Fullerenes Encapsulating Carbon Nanotubes

Structural and Vibrational Properties of C60 and C70 Fullerenes Encapsulating Carbon Nanotubes

Anharmonic adlayer vibrations on the Si(111):H surface

Experimental and numerical exploration of intrinsic localized modes in an atomic lattice

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