High‐resolution<scp>R</scp>aman Spectroscopy of Gases

Weber, Alfons

doi:10.1002/9780470749593.hrs047

Cited by 31 publications

(7 citation statements)

References 263 publications

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“…Prior to each RCS experiment, the experimental apparatus function G ( t ) is measured via the zero time Kerr peak of Ar gas. The stimulated Raman response of the medium to the three laser pulses is described by the third-order susceptibility χ (3) ( t ), which can be modeled for t > 0 as where C is a proportionality constant and b J , K ,ν is an amplitude coefficient that includes the rotational and vibrational level population factors, the rotational ( g J , K ) and vibrational ( g ν ) degeneracies, nuclear spin statistics, and the rotational Raman intensity coefficients for anisotropic Raman scattering (Placzek–Teller factors). − The Δω J , K ,ν in eq are the frequencies of all rotational Raman-allowed transitions from states with rotational quantum numbers J , K and vibrational quantum number ν that can undergo stimulated Raman transitions within the femtosecond laser bandwidth of ∼100 cm –1 . While the classical bent and twist equilibrium geometries are asymmetric, the vibrational ν = 0 level is delocalized over all 20 stationary points (see Figure ), which renders cyclopentane an effective symmetric top molecule.…”

Section: Degenerate Four-wave Mixing Theory and Rcs Signal Analysismentioning

confidence: 99%

Probing the Structure, Pseudorotation, and Radial Vibrations of Cyclopentane by Femtosecond Rotational Raman Coherence Spectroscopy

et al. 2015

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The 10 nJ pulses from a Kerr-lens mode-locked Ti:sapphire oscillator (Mai Tai, SpectraPhysics) are amplified in a Ti:sapphire multipass chirped-pulse amplifier system (ODIN DQC, Quantronix), which is pumped by a 14 W pulsed frequency- The output of the fs laser system is reduced to a laser pulse energy between 75 − 120 µJ and split into three equally intense pump, dump and probe beams, which are aligned in a forward BOXCARS degenerate four-wave mixing (DFWM) arrangement, and focused by an f = 1000 mm achromatic lens into the center of either a 1.0 m long stainless-steel gas-cell or into the supersonic jet vacuum chamber. The probe beam runs over a retroreflector that is mounted on a high-precision 1000 mm long delay stage, housed in a vacuum tank with 800 nm AR coated windows that is evacuated to < 10 −3 mbar. The time-delay of the probe pulse is by measuring the retroreflector displacement with a two-axis He-Ne laser interferometric system (SP2000 D; SIOS GmbH) with an accuracy of ±30 nm. After the output window of gas-cell or jet vacuum chamber, the three input beams are blocked by a mask, while the DFWM signal beam is collimated, spatially filtered and detected by a thermoelectrically cooled GaAs photomultiplier (H7422-50, Hamamatsu). The signals are recorded with a 1 GHz/8-bit oscilloscope at a sweep rate of 8 GHz/s. The experiment is controlled and the data acquired by a PC using LabView.

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Section: Degenerate Four-wave Mixing Theory and Rcs Signal Analysismentioning

confidence: 99%

Probing the Structure, Pseudorotation, and Radial Vibrations of Cyclopentane by Femtosecond Rotational Raman Coherence Spectroscopy

et al. 2015

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“…However, compared to the treatments of the symmetric top molecules TFB and HFB, the asymmetric-top Raman RCS simulations are significantly more involved: First, the asymmetric-top rotational eigenfunctions and energy eigenvalues E(J, K 1 , K −1 ) must be computed numerically, in contrast to symmetric tops whose rotational level energies can be expressed analytically. Second, the rotational Raman transition intensities of symmetric tops are given analytically by the Placzek-Teller factors, 4,5 which involve only a few multiplication and division operations, while for asymmetric tops, the evaluation of the rotational Raman intensities involves ∼J 3 floating-point operations. 4 Third, the three different diagonal (in some cases also off-diagonal) components of the molecular polarizability tensor of asymmetric-top molecules give rise to different rotational transient types.…”

Section: Introductionmentioning

confidence: 99%

Rotational constants and structure of para-difluorobenzene determined by femtosecond Raman coherence spectroscopy: A new transient type

Den

Frey

Felker

et al. 2015

The Journal of Chemical Physics

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Articles you may be interested inAccurate rotational constant and bond lengths of hexafluorobenzene by femtosecond rotational Raman coherence spectroscopy and ab initio calculations J. Chem. Phys. 141, 194303 (2014) Femtosecond Raman rotational coherence spectroscopy (RCS) detected by degenerate four-wave mixing is a background-free method that allows to determine accurate gas-phase rotational constants of non-polar molecules. Raman RCS has so far mostly been applied to the regular coherence patterns of symmetric-top molecules, while its application to nonpolar asymmetric tops has been hampered by the large number of RCS transient types, the resulting variability of the RCS patterns, and the 10 3 -10 4 times larger computational effort to simulate and fit rotational Raman RCS transients. We present the rotational Raman RCS spectra of the nonpolar asymmetric top 1,4-difluorobenzene (para-difluorobenzene, p-DFB) measured in a pulsed Ar supersonic jet and in a gas cell over delay times up to ∼2.5 ns. p-DFB exhibits rotational Raman transitions with ∆J = 0, 1, 2 and ∆K = 0, 2, leading to the observation of J−, K−, A−, and C-type transients, as well as a novel transient (S-type) that has not been characterized so far. The jet and gas cell RCS measurements were fully analyzed and yield the ground-state (v = 0) rotational constants A 0 = 5637.68(20) MHz, B 0 = 1428.23(37) MHz, and C 0 = 1138.90(48) MHz (1σ uncertainties). Combining the A 0 , B 0 , and C 0 constants with coupled-cluster with single-, double-and perturbatively corrected triple-excitation calculations using large basis sets allows to determine the semi-experimental equilibrium bond lengths r e (C 1 -C 2 ) = 1.3849(4) Å, r e (C 2 -C 3 ) = 1.3917(4) Å, r e (C-F) = 1.3422(3) Å, and r e (C 2 -H 2 ) = 1.0791(5) Å. C 2015 AIP Publishing LLC. [http://dx

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“…Promising Raman detection schemes are based on the stimulated Raman method, including inverse Raman spectroscopy, coherent anti-Stokes Raman spectroscopy (CARS), or photoacoustic stimulated Raman spectroscopy (PARS). [1][2][3][4] However, these techniques involve complex arrangements and require two different wavelengths from high power lasers.…”

Section: Introductionmentioning

confidence: 99%

Cavity-enhanced Raman spectroscopy with optical feedback cw diode lasers for gas phase analysis and spectroscopy

Salter

Chu

Hippler

2012

Analyst

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A variant of cavity-enhanced Raman spectroscopy (CERS) is introduced, in which diode laser radiation at 635 nm is coupled into an external linear optical cavity composed of two highly reflective mirrors. Using optical feedback stabilisation, build-up of circulating laser power by 3 orders of magnitude occurs. Strong Raman signals are collected in forward scattering geometry. Gas phase CERS spectra of H(2), air, CH(4) and benzene are recorded to demonstrate the potential for analytical applications and fundamental molecular studies. Noise equivalent limits of detection in the ppm by volume range (1 bar sample) can be achieved with excellent linearity with a 10 mW excitation laser, with sensitivity increasing with laser power and integration time. The apparatus can be operated with battery powered components and can thus be very compact and portable. Possible applications include safety monitoring of hydrogen gas levels, isotope tracer studies (e.g., (14)N/(15)N ratios), observing isotopomers of hydrogen (e.g., radioactive tritium), and simultaneous multi-component gas analysis. CERS has the potential to become a standard method for sensitive gas phase Raman spectroscopy.

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High‐resolutionRaman Spectroscopy of Gases

Cited by 31 publications

References 263 publications

Probing the Structure, Pseudorotation, and Radial Vibrations of Cyclopentane by Femtosecond Rotational Raman Coherence Spectroscopy

Probing the Structure, Pseudorotation, and Radial Vibrations of Cyclopentane by Femtosecond Rotational Raman Coherence Spectroscopy

Rotational constants and structure of para-difluorobenzene determined by femtosecond Raman coherence spectroscopy: A new transient type

Cavity-enhanced Raman spectroscopy with optical feedback cw diode lasers for gas phase analysis and spectroscopy

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