Temperature dependence of the low- and high-frequency Raman scattering from liquid water

Walrafen, G. E.; Fisher, Michal; Hokmabadi, M. S.; Yang, Wenshu

doi:10.1063/1.451384

Cited by 574 publications

(382 citation statements)

References 59 publications

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“…The isosbestic point refers to the wavenumber at which spectra taken at different conditions (e.g., temperatures, pressures, and potentials) cross putatively due to the equilibrium between the hydrogenbonded and nonhydrogen-bonded hydroxyl species [19], [20]. The isosbestic point value is this study is well within the determined 3,400-3,500 cm À1 range for the liquid water under different polarization conditions [9], [19].…”

supporting

confidence: 48%

“…Possible vibrational modes include symmetric stretching (m 1 ), an overtone of bending (2m 2 ), and antisymmetric stretching (m 3 ) [6], but experimental studies indicate that only the m 1 mode is prominent in the Raman measurements [7], [8]. The width and multipeak shape of the m 1 mode has been attributed to coupling of the hydroxyl group stretching with the energy of intra-and intermolecular hydrogen bonds [6], [9]- [11]. Formation of these hydrogen bonds can reduce the wavenumber [7] and amplitude [12] of this hydroxyl stretching motion.…”

mentioning

confidence: 99%

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Thermal Monitoring: Raman Spectrometer System for Remote Measurement of Cellular Temperature on a Microscopic Scale

Pikov

Siegel

2010

IEEE Eng. Med. Biol. Mag.

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supporting

confidence: 48%

mentioning

confidence: 99%

Thermal Monitoring: Raman Spectrometer System for Remote Measurement of Cellular Temperature on a Microscopic Scale

Pikov

Siegel

2010

IEEE Eng. Med. Biol. Mag.

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“…These correspond to the two broad bands centered at about 50 cm −1 and 200 cm −1 , generally addressed in the literature [23][24][25][26] as "bending" and "stretching" modes of the hydrogen-bond network, respectively. At long times the signal shows a monotonic decay; in the first OKE investigations it was interpreted as a bi-exponential relaxation, due to single molecule orientational dynamics 27 .…”

Section: Hd-oke Water Datamentioning

confidence: 99%

Optical Kerr effect of liquid and supercooled water: The experimental and data analysis perspective

Taschin¹,

Bartolini²,

Eramo³

et al. 2014

The Journal of Chemical Physics

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The time-resolved optical Kerr effect spectroscopy (OKE) is a powerful experimental tool enabling accurate investigations of the dynamic phenomena in molecular liquids. We introduced innovative experimental and fitting procedures, that permit a safe deconvolution of sample response function from the instrumental function. This is a critical issue in order to measure the dynamics of sample presenting weak signal, e.g. liquid water. We report OKE data on water measuring intermolecular vibrations and the structural relaxation processes in an extended temperature range, inclusive of the supercooled states. The unpreceded data quality makes possible a solid comparison with few theoretical models; the multi-mode Brownian oscillator model, the Kubo's discrete random jump model and the schematic mode-coupling model. All these models produce reasonable good fits of the OKE data of stable liquid water, i.e. over the freezing point. The features of water dynamics in the OKE data becomes unambiguous only at lower temperatures, i.e. for water in the metastable supercooled phase. Hence this data enable a valid comparison between the model fits. We found that the schematic mode-coupling model provides the more rigorous and complete model for water dynamics, even if is intrinsic hydrodynamic approach hide the molecular informations.

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“…26 In the present work, the complete set of the parameters for the effective Kihara potential function (eqs 27-29) have been used for the RDF calculations of water molecules by the integral equation method and the constants of these parameters have been evaluated.…”

Section: Integration Of the Above Equations Leads Tomentioning

confidence: 99%

Application of Integral Equation Joined with the Chain Association Theory to Study Molecular Association in Sub- and Supercritical Water

2001

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Abstract:In this report, the Percus-Yevick and the Ornestein-Zernike integral equations are solved simultaneously for the radial distribution functions of water at various state conditions, including sub-and supercritical states. The intermolecular potential function used in this study consists of an effective Kihara potential, which is derived for associated fluids. For derivation of the effective potential function, water is considered as a mixture of associated species due to hydrogen bonding. The contribution of hydrogen bonding is considered in the formulation of the effective Kihara potential parameters through the application of the analytic chain association theory. There is a good agreement between the present calculations and the experimental data in predicting the oxygen-oxygen radial distribution function near the critical point and at supercritical conditions for which experimental data are available. It is also concluded that at supercritical conditions a considerable degree of hydrogen bonding may be still present in the form of linear chain association. Therefore, the chain association model is valid near the critical point and at supercritical conditions instead of other structure models for the investigations on molecular structure of water.calculations, they ignored the temperature dependency of the intermolecular distances between the nearest neighboring molecules.On the basis of the reported experimental data, 2 it is evident that the intermolecular distances between the nearest neighbors are temperature-dependent. Then this temperature dependency should be accounted for in the potential function to be used in the RDF calculations. In this work, the complete form of the effective Kihara potential function, which includes the parameters for the temperature dependency of the nearest neighbors, is used to calculate the RDF (oxygen-oxygen radial distribution function) for water molecules. The method of RDF calculations in this work is based on the application of the integral equation, which, as the results obtained indicate, can be considered as an accurate approach and leads to evaluating the RDF in the whole range of intermolecular distance variations. Also, a new set of constants for the parameters of an effective Kihara potential function is proposed.From a structural viewpoint, the results of these calculations substantiate the previous conclusion by the other workers 2,7,9 that at supercritical conditions, hydrogen bonding in the form of linear chain associations exists between water molecules. In eq 1, R is the polarizability factor, µ is the dipole moment, and σ are energy and size parameters, and r is the intermolecular separation. In this potential function, the dielectric property of pure water has been noted, and the dielectric dipole moment (µ 4 /3kT) and induced dipole (2µ 2 R) terms have been introduced in the intermolecular potential function. This equation is used in our RDF calculations. The results (Figure 1) indicate is another alternative to represent the intermolecular pote...

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Temperature dependence of the low- and high-frequency Raman scattering from liquid water

Cited by 574 publications

References 59 publications

Thermal Monitoring: Raman Spectrometer System for Remote Measurement of Cellular Temperature on a Microscopic Scale

Thermal Monitoring: Raman Spectrometer System for Remote Measurement of Cellular Temperature on a Microscopic Scale

Optical Kerr effect of liquid and supercooled water: The experimental and data analysis perspective

Application of Integral Equation Joined with the Chain Association Theory to Study Molecular Association in Sub- and Supercritical Water

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