Chemical Thermodynamics of Ultrasound Speed in Solutions and Liquid Mixtures

Reis, João Carlos R.; Santos, Ângela F.S.; Lampreia, Isabel M.S.

doi:10.1002/cphc.200900709

Cited by 24 publications

(13 citation statements)

References 44 publications

(45 reference statements)

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“…A similar situation was recently encountered for the ultrasound speed. [5] By noting that aÀb = (a 2 Àb 2 )/(a+b), it follows from Equations (6), (10) and (11) …”

Section: Ideal Refractive Index Of Mixingmentioning

confidence: 98%

“…[5] Here, we draw on the fact that both properties are related to the speed of propagation of waves in liquids to describe unmixed refractive indices in close analogy with unmixed ultrasound speeds.…”

Section: Refractive Index Before Mixingmentioning

confidence: 99%

“…Thus, we introduce the concept of refractive index before mixing two portions of pure liquid substances. This development is a natural extension of the recently presented idea of speed of sound before mixing, [5] because the refractive index is proportional to the reciprocal of the speed of light. Then, on the basis of other contributions leading to the estimation of relative permittivities of thermodynamically ideal liquid mixtures, [6] we obtain an equation describing the dependence on composition of the ideal refractive index.…”

Section: Introductionmentioning

confidence: 95%

“…Recently, Balankina [9] has argued that excess volumetric properties of liquid mixtures should be easier to interpret in terms of the dependence on composition of relative excess properties, the latter being defined as the ratio between excess and ideal values. We have already shown [5] that this is a powerful concept that yields a simple thermodynamic equation interrelating the relative excess values for ultrasound speeds, molar volumes and molar isentropic compressions of binary systems.…”

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confidence: 97%

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Refractive Index of Liquid Mixtures: Theory and Experiment

et al. 2010

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An innovative approach is presented to interpret the refractive index of binary liquid mixtures. The concept of refractive index "before mixing" is introduced and shown to be given by the volume-fraction mixing rule of the pure-component refractive indices (Arago-Biot formula). The refractive index of thermodynamically ideal liquid mixtures is demonstrated to be given by the volume-fraction mixing rule of the pure-component squared refractive indices (Newton formula). This theoretical formulation entails a positive change of refractive index upon ideal mixing, which is interpreted in terms of dissimilar London dispersion forces centred in the dissimilar molecules making up the mixture. For real liquid mixtures, the refractive index of mixing and the excess refractive index are introduced in a thermodynamic manner. Examples of mixtures are cited for which excess refractive indices and excess molar volumes show all of the four possible sign combinations, a fact that jeopardises the finding of a general equation linking these two excess properties. Refractive indices of 69 mixtures of water with the amphiphile (R,S)-1-propoxypropan-2-ol are reported at five temperatures in the range 283-303 K. The ideal and real refractive properties of this binary system are discussed. Pear-shaped plots of excess refractive indices against excess molar volumes show that extreme positive values of excess refractive index occur at a substantially lower mole fraction of the amphiphile than extreme negative values of excess molar volume. Analysis of these plots provides insights into the mixing schemes that occur in different composition segments. A nearly linear variation is found when Balankina's ratios between excess and ideal values of refractive indices are plotted against ratios between excess and ideal values of molar volumes. It is concluded that, when coupled with volumetric properties, the new thermodynamic functions defined for the analysis of refractive indices of liquid mixtures give important complementary information on the mixing process over the whole composition range.

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“…A similar situation was recently encountered for the ultrasound speed. [5] By noting that aÀb = (a 2 Àb 2 )/(a+b), it follows from Equations (6), (10) and (11) …”

Section: Ideal Refractive Index Of Mixingmentioning

confidence: 98%

Section: Refractive Index Before Mixingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 95%

mentioning

confidence: 97%

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Refractive Index of Liquid Mixtures: Theory and Experiment

et al. 2010

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“…As noted in the previous paper by one of us [36], a similar relationship between u D and K E S was reported for various systems with two selfassociated compounds and it seems to be a general feature for such systems. As reported recently [37], a detailed analysis of the above relation seems promising for better understanding of the information obtained from acoustic experiments.…”

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confidence: 94%

Thermodynamic and acoustic properties of binary mixtures of 1-butanol with 1,2-butanediol. The comparison with the results for 1,3-, and 1,4-butanediol

Góralski

Godula

Zorębski

2014

The Journal of Chemical Thermodynamics

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Thermodynamic and Acoustic Properties of Mixtures of Dibromomethane + Heptane

et al. 2010

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Densities and speeds of ultrasound in binary mixtures of dibromomethane with heptane have been measured within the temperature range from 288.15 K to 318.15 K. From the experimental data, the thermodynamic excess volume, molar isobaric expansion, molar isentropic compression, and ultrasonic speed were calculated. The excess volume and excess isentropic compression have opposite signs, whereas the excess isobaric expansion is an S-shaped function of the mole fraction. An explanation was suggested to account for the excesses in terms of intermolecular interactions. It involved energetic and steric factors. Moreover, it was shown that the positive excess sound speed results almost entirely from the negative excess compression.

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Chemical Thermodynamics of Ultrasound Speed in Solutions and Liquid Mixtures

Cited by 24 publications

References 44 publications

Refractive Index of Liquid Mixtures: Theory and Experiment

Refractive Index of Liquid Mixtures: Theory and Experiment

Thermodynamic and acoustic properties of binary mixtures of 1-butanol with 1,2-butanediol. The comparison with the results for 1,3-, and 1,4-butanediol

Thermodynamic and Acoustic Properties of Mixtures of Dibromomethane + Heptane

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