Rovibrational Energy Transfer in Methane Excited to 2ν3 in CH4−N2 Mixtures from Double-Resonance Measurements

Ménard‐Bourcin, F.; Boursier, C.; Doyennette, L.; Ménard, J.

doi:10.1021/jp011712u

Cited by 27 publications

(25 citation statements)

References 13 publications

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“…The extended model includes 311 reversible reactions with the following species: For thermally nonequilibrium conditions, where the distribution of vibrational energy in reactive molecules is specified by vibrational temperatures T ξ , the set of chemical reactions should be supplemented by the channels of vibrational-energy intermode (VV ) exchange and the pathways of vibrationaltranslational (VT) relaxation. Within the framework of the mode-resolved model adopted in the present work, we considered the VV exchange between the symmetric, deformation, and asymmetric (ν 1 , ν 2 , and ν 3 ) modes of H 2 O molecules, the modes of molecules of H 2 (ν 4 ), O 2 (ν 5 ), OH(ν 6 ), N 2 (ν 7 ), NO(ν 8 ), and CO(ν 21 ), the symmetric, deformation, and asymmetric modes of molecules of NO 2 (ν 9 , ν 10 , ν 11 ), HO 2 (ν 12 , ν 13 , ν 14 ), O 3 (ν 15 , ν 16 , ν 17 ), and CO 2 (ν 18 , ν 19 , ν 20 ), and the VT relaxation processes for the modes ν 2 , ν 4 , ν 5 , ν 6 , ν 7 , ν 8 , ν 10 , ν 14 , ν 16 , ν 19 , and ν 21 . It is known that vibrational relaxation in hydrocarbon molecules proceeds much faster than the relaxation in diatomic and triatomic molecules [19].…”

Section: Methodology and Kinetic Modelmentioning

confidence: 99%

“…Within the framework of the mode-resolved model adopted in the present work, we considered the VV exchange between the symmetric, deformation, and asymmetric (ν 1 , ν 2 , and ν 3 ) modes of H 2 O molecules, the modes of molecules of H 2 (ν 4 ), O 2 (ν 5 ), OH(ν 6 ), N 2 (ν 7 ), NO(ν 8 ), and CO(ν 21 ), the symmetric, deformation, and asymmetric modes of molecules of NO 2 (ν 9 , ν 10 , ν 11 ), HO 2 (ν 12 , ν 13 , ν 14 ), O 3 (ν 15 , ν 16 , ν 17 ), and CO 2 (ν 18 , ν 19 , ν 20 ), and the VT relaxation processes for the modes ν 2 , ν 4 , ν 5 , ν 6 , ν 7 , ν 8 , ν 10 , ν 14 , ν 16 , ν 19 , and ν 21 . It is known that vibrational relaxation in hydrocarbon molecules proceeds much faster than the relaxation in diatomic and triatomic molecules [19]. According to these data, the vibrations of hydrocarbon molecules were assumed to be in thermodynamic equilibrium with translational degrees of freedom.…”

Section: Methodology and Kinetic Modelmentioning

confidence: 99%

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Initiation of combustion by laser-induced excitation of molecular vibrations of reactants

2006

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The features of combustion initiation in H 2 /air and CH 4 (C 2 H 2 )/air mixtures under laser-induced excitation of the asymmetric mode of ozone molecules added in a small amount to the mixture are analyzed. It was shown that such an approach to supply radiation energy to the combustible mixtures reduces the induction time and decreases the ignition temperature at a small energy of laser radiation delivered to the mixture. These effects are explained mostly by two factors -the intensification of chain reactions due to acceleration of O-atom formation during dissociation of vibrationally excited O 3 molecules and the heating of the mixture due to a faster decomposition of O 3 molecules. The considered method of ignition/combustion control is much more effective (by a factor of 10-100) than the method based on heating the gas by resonance laser radiation in the case where the characteristic time of highly reactive radical and atom formation does not exceed significantly the relaxation time of the asymmetric mode of the O 3 molecule.

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Section: Methodology and Kinetic Modelmentioning

confidence: 99%

Section: Methodology and Kinetic Modelmentioning

confidence: 99%

Initiation of combustion by laser-induced excitation of molecular vibrations of reactants

2006

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“…A complete description of the spectroscopic properties of CH 4 is given in Ref. [15] and the rovibrational energy transfer processes in CH 4 -N 2 /O 2 mixtures are also discussed in a series a papers [15,16,24]. We just recall here the main spectroscopic characteristics of CH 4 molecules that are essential for the understanding of our experimental results.…”

Section: 2mentioning

confidence: 99%

Near-infrared laser photoacoustic detection of methane: the impact of molecular relaxation

2005

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A photoacoustic sensor has been developed for trace-gas monitoring using a near-infrared semiconductor laser emitting in the 2ν 3 band of methane at 1.65 µm. The apparatus was designed for on-line process control in the manufacturing of the novel low-water-peak fibres developed for optical telecommunications. The importance of collisional relaxation processes in the generation of the photoacoustic signal is reported in the particular case of CH 4 detection in dry O 2 and O 2 -N 2 mixtures. The negative influence of these effects results in a strongly reduced and phase-shifted photoacoustic signal, induced by a fast resonant coupling between the vibrational states of methane and oxygen, associated with the slow relaxation of the excited oxygen molecules. An unusual parabolic response of the sensor with respect to the methane concentration has been observed and is discussed. Finally, the beneficial effect of several species, including water vapour and helium, acting as a catalyst to hasten the relaxation of the CH 4 -O 2 system, is demonstrated.PACS 42.62.Fi; 33.20.Ea; 34.50.Ez IntroductionInfrared photoacoustic spectroscopy (PAS) is widely recognized for its high performances in trace-gas monitoring and is one of the most sensitive techniques to measure low gas concentrations at atmospheric pressure [1]. The high sensitivity of PAS mainly results from its zero-background nature, which means that no signal is produced in the absence of an absorbing species. Furthermore, one of the most outstanding features of this technique is its achromaticity: the response of a photoacoustic (PA) sensor, represented by the cell constant (i.e. the PA signal normalized by the laser power and absorption coefficient), is usually independent of the laser excitation wavelength (however, a few exceptions may occur in some particular situations, as will be discussed later). It means that the same PA detector can be used with any type of laser and at any wavelength, from ultraviolet to mid infrared (MIR), with identical performances in terms of cell constant (provided that a suitable window material is used in the PA cell). This is definitively not the case for other high u Fax: +41-21-693-26-14, E-mail: stephane.schilt@epfl.ch sensitivity laser spectroscopy techniques, such as wavelengthor frequency-modulation spectroscopy (WMS/FMS), cavity ring-down spectroscopy (CRDS) or intracavity laser absorption spectroscopy (ICLAS), which all make use of optical detection that has poorer performances in the MIR region. Indeed, not only is the sensitivity of MIR photodiodes strongly reduced in comparison to near-infrared (NIR) ones, but also MIR detectors require low-temperature operation and are much more expensive than NIR detectors.For several years, there has been much interest in the use of NIR semiconductor lasers in PAS, such as distributedfeedback (DFB) lasers mass produced for the optical telecommunications market, whereas, primarily, it has been predominantly implemented using MIR gas lasers (CO or CO 2 lasers). Extreme detectio...

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“…It was believed until recently that vibrational relaxation in hydrocarbon molecules proceeds rather rapidly, and the translational, rotational, and vibrational degrees of freedom of these molecules in combustion of hydrocarbon fuels (even in the presence of shock waves or in the detonation mode of combustion) could be assumed with good accuracy to be thermodynamically equilibrium. The measurements of the times of vibrational relaxation in a CH 4 molecule [18,19], however, show that this assumption can prove to be invalid. Therefore, a finite time of vibrational-translational relaxation in a CH 4 molecule was taken into account in constructing the thermally nonequilibrium model of chemical kinetics.…”

Section: Formulation Of the Problem And Kinetic Modelmentioning

confidence: 99%

“…A typical decrease in gas temperature in the zone adjacent to the shock-wave front should also be noted; this decrease is more pronounced in the case of the thermal action of the discharge. Figure 4 shows the behavior of translational (T ) and vibrational (T ξ ) temperatures of the basic compo- 5 , and T 6 ), H 2 (T 7 ), OH (T 8 ), CO (T 15 ), and CH 4 (T 19 )] behind the shock-wave front (M 0 = 8 and β = 25 • ) for E s = 3 · 10 −2 J/cm 3 and p 0 = 10 4 Pa for the cases where the discharge energy is spent both on activation of O 2 molecules and on heating of the mixture. It is seen that the decrease in T behind the shock-wave front in the case of simple heating of the gas is caused by excitation of molecular vibrations of CH 4 and O 2 .…”

Section: Kinetics Of Combustion Initiation Behind the Shock-wave Frontmentioning

confidence: 99%

Initiation of combustion of a CH4-O2 mixture in a supersonic flow with excitation of O2 molecules by an electric discharge

Starik

Lukhovitskii

Титова

2008

Combust Explos Shock Waves

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The possibility of intensification of ignition of a methane-oxygen mixture in a supersonic flow behind the front of an oblique shock wave by means of excitation of O 2 molecules to the states a 1 Δ g and b 1 Σ + g in an electric discharge is discussed. Through numerical simulations, activation of O 2 molecules by an electric discharge is demonstrated to speed up chain reactions in the CH 4 -O 2 mixture and to reduce the induction-zone length. Even a small amount of energy input to O 2 molecules in the discharge (≈3 ·0 −2 J/cm 3 ) can reduce the ignition-delay length by a factor of hundreds and initiate combustion at distances of ≈1 m from the discharge zone at comparatively low temperatures of the gas behind the front (≈1000 K) and moderate pressures (≈10 5 Pa). Excitation of O 2 molecules by an electric discharge is much more efficient than simple heating of the mixture.

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Rovibrational Energy Transfer in Methane Excited to 2ν₃ in CH₄−N₂ Mixtures from Double-Resonance Measurements

Cited by 27 publications

References 13 publications

Initiation of combustion by laser-induced excitation of molecular vibrations of reactants

Initiation of combustion by laser-induced excitation of molecular vibrations of reactants

Near-infrared laser photoacoustic detection of methane: the impact of molecular relaxation

Initiation of combustion of a CH4-O2 mixture in a supersonic flow with excitation of O2 molecules by an electric discharge

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