The system methylcyclohexane/polystyrene. Experimental critical curves, cloud‐point and spinodal isopleths, and their description with a semi‐phenomenological treatment

Vanhee, Sabine; Kiepen, Friedheinz; Brinkmann, Dirk; Borchard, W.; Koningsveld, R.; Berghmans, Hugo

doi:10.1002/macp.1994.021950233

Cited by 23 publications

(10 citation statements)

References 42 publications

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“…A distinct improvement of the quality of the calculated CPC is not reached by changing the concentration dependence of the g function from the linear type of b g to the squared type of c g . The closed form of the g function d g , which has been introduced by Koningsveld and Kleintjens, leads to a reasonable locus of the calculated CPC . But the shape of the calculated curve, which is the dotted curve in Figure , also deviates from the very flat one of the experimental CPC.…”

Section: Resultsmentioning

confidence: 81%

“…For a Gibbs free enthalpy of mixing according to eq 3 it follows that and where γ represents the phase indices ‘ or ‘‘ and i = 2, 3, ..., N and r̄ n is the number average of r i . The parameter χ 1 γ represents the interaction parameter of the solvent in the phase γ, and the parameter χ p γ represents the same of the polymer. ,,, They are defined by and By the use of the distribution coefficient σ, it follows that ,, with which reflects the fractionation of a polymer component i enriched either in the dilute or in the concentrated coexisting phase. By a summation over all polymer species i , eq 7a leads to the polymer concentration φ p ‘‘: Assuming a certain mmd in the original polymer sample and assuming an appropriate thermodynamic framework, a stepwise iteration may be performed that should give the CPC and the shadow curve of the system.…”

Section: Introductionmentioning

confidence: 99%

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Thermodynamic Properties of Poly(ethylene glycol)/Water Systems. 1. A Polymer Sample with a Narrow Molar Mass Distribution

Fischer¹,

Borchard²,

Karas³

1996

J. Phys. Chem.

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Liquid−liquid demixing experiments of a poly(ethylene glycol)/water system have been performed. The polymer is characterized by a nominal molar mass of 6000 g mol-1 and a narrow molar mass distribution. The cloud-point curve of the system and a large number of phase volume ratios at different polymer concentrations and temperatures have been measured. With these results the critical coordinates and the shadow curve of the system have been determined using the volume conservation equation. Generally, the system behaves like a binary one. The miscibility gap is well described using the scaling theory up to temperatures of about 12 K above the lower critical point. The cloud-point and the shadow curve of the system have been computed using the Flory−Huggins theory. For the first time thermodynamic parameters have been used that are calculated directly from the concentrations of coexisting phases obtained by evaluation of phase volume ratio measurements. The examined forms of the interaction function g of the base molar free enthalpy of mixing ΔḠ M do not describe the system satisfactorily.

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Section: Resultsmentioning

confidence: 81%

Section: Introductionmentioning

confidence: 99%

Thermodynamic Properties of Poly(ethylene glycol)/Water Systems. 1. A Polymer Sample with a Narrow Molar Mass Distribution

Fischer¹,

Borchard²,

Karas³

1996

J. Phys. Chem.

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“…PS/MCH solutions form examples of at least the lower part of the reentrant diagram illustrated in Figure 4. Previous observations of the demixing diagram for PS/ MCH at modestly elevated pressures have been reported by Vanhee et al 44 (0.1 < P/MPa < 90), Van Hook et al, 4,9,10 Enders and de Loos, 45 Hosokawa, Nakata, and Dobashi, 46 and Wells et al 47 and correlated by Imre and Van Hook. 6 The earlier work establishes the existence of a lower hypercritical temperature (T hyp L ) 305 K, 55 MPa, at M w (PS) ) 3 × 10 4 ), and points to the existence of a lower hypercritical pressure at P < 0, but not too deep (P hyp L ) ∼34 010 K, ∼-15 ( 3 MPa at M w (PS) ) 3 × 10 4 , dropping off to P hyp L ) ∼360 ( 10 K, ∼-10 ( 3 MPa, at M w (PS) ) 2 × 10 6 ).…”

Section: Dls Correlation Radii In the (P T ψ C ) Projection For Ps/mc...mentioning

confidence: 72%

Dynamic Light Scattering of Polymer/Solvent Solutions Under Pressure. Near-Critical Demixing (0.1 < P/MPa < 200) for Polystyrene/Cyclohexane and Polystyrene/Methylcyclohexane

1999

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A conveniently sized high-pressure scattering cell used for 90° DLS (dynamic light scattering) measurements on polymer solutions is described (0 < P/MPa < 200; 283 < T/K < 373). DLS parameters are reported for semidilute solutions of polystyrene (PS) of various molecular weight in ϑ-solvents (cyclohexane (CH) and methylcyclohexane (MCH)), above and below T ϑ, and at high enough concentration to ensure that precipitation, when it occurs, follows spinodal decomposition/percolation. In the homogeneous region, close to and above T ϑ, the correlograms, initially monomodal and diffusive, split at high pressure. The intensity and the correlation radius of the diffusive mode diverge as critical demixing is approached during pressure or temperature quenches. That process is described in the (T,P)ψ cr plane using a multidimensional reduced scaling formalism developed for the purpose. The analysis of the scattering and the phase equilibrium data for PS/CH is complicated by the pressure dependence of the CH freezing curve, but that for PS/MCH nicely exemplifies behavior across a good part of the (T,P)ψ cr reentrant miscibility island showing multiple hypercritical points. It has been discussed in that context.

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“…Although in most cases increased pressure improves SQ, that behavior is not universal. Others have reported that increasing the pressure improves SQ by transforming a θ solvent into a good solvent17–21 or a poor solvent into a θ solvent 22, 23. The results at room temperature show that SQ improves with pressure ( d SQ/ dP > 0) in the good (PS/toluene and PS/chloroform) and poor (PS/MCH) solvents studied.…”

Section: Discussionmentioning

confidence: 86%

“…Others have employed liquid–liquid phase equilibria to determine dT UCST / dP , another measure of SQ. In this way, several groups have reported that increasing pressure improves SQ by transforming a θ solvent into a good solvent17–21 or a poor solvent into a θ solvent 22, 23. Although in most cases increased pressure does improve SQ, that behavior is not universal.…”

Section: Discussionmentioning

confidence: 99%

Pressure dependence of the second virial coefficient of dilute polystyrene solutions

Moses

Hook

2003

J Polym Sci B Polym Phys

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The pressure derivatives of the second virial coefficients [dA 2 /dP; 0.1 Յ P (MPa) Յ 35.0] for dilute polystyrene (PS) solutions in good, , and poor solvents were measured with static light scattering. The solvent quality improved (dA 2 /dP Ͼ 0) in the good and poor solvents that we investigated (toluene, chloroform; and methylcyclohexane) but deteriorated (dA 2 /dP Ͻ 0) in solvents (cyclohexane and 50-50 cis,transdecalin). The effects of temperature [22 Ͻ T (°C) Ͻ 45] and molecular weight [25 ϫ 10 3 Ͻ weight-average molecular weight (amu mol Ϫ1 ) Ͻ 900 ϫ 10 3 ] on dA 2 /dP for PS/ cyclohexane solutions were examined.

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The system methylcyclohexane/polystyrene. Experimental critical curves, cloud‐point and spinodal isopleths, and their description with a semi‐phenomenological treatment

Cited by 23 publications

References 42 publications

Thermodynamic Properties of Poly(ethylene glycol)/Water Systems. 1. A Polymer Sample with a Narrow Molar Mass Distribution

Thermodynamic Properties of Poly(ethylene glycol)/Water Systems. 1. A Polymer Sample with a Narrow Molar Mass Distribution

Dynamic Light Scattering of Polymer/Solvent Solutions Under Pressure. Near-Critical Demixing (0.1 < P/MPa < 200) for Polystyrene/Cyclohexane and Polystyrene/Methylcyclohexane

Pressure dependence of the second virial coefficient of dilute polystyrene solutions

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