Thermodynamics of polystyrene solutions. Part 2.—Polystyrene and ethylbenzene

Transactions of The Faraday Society Pub Date : 1971-01-01 DOI:10.1039/TF9716702270

H. Höcker, P. Flory

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引用次数: 46

Abstract

The volume change on mixing polystyrene with ethylbenzene has been determined directly at 25°C. It is negative and amounts to ca. 0.30 % of the total volume at ϕ2= 0.5. Osmotic pressures have been measured at 10°, 35°, and 60°C in the concentration range ϕ2= 0.09 to 0.27. The temperature coefficient of the reduced residual chemical potential χ is close to zero; hence the heat of dilution is very small. The entropy of dilution is positive but small. The statistical thermodynamic theory employed in the preceding paper accounts for the sign and magnitude of the excess volume. The experimental partial molar entropies are much smaller than the combinatory contribution alone would allow. This finding and the small negative enthalpy of dilution indicated by recent work of Palmen are shown to arise mainly from equation-of-state terms of the newer theory. The parameter X12 representing the exchange enthalpy is positive and small, as should be expected for this system. The observed increase in χ with concentration is well reproduced by the theory. Thermal expansivities and thermal pressure coefficients of ethylbenzene have been determined at atmospheric pressure from 10° to 90°C.

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聚苯乙烯溶液的热力学。第2部分。-聚苯乙烯和乙苯

在25℃下直接测定了聚苯乙烯与乙苯混合时的体积变化。它是负的，在ϕ2= 0.5时约占总容积的0.30%。渗透压已在10°、35°和60°C的浓度范围内测得，浓度范围为ϕ2= 0.09至0.27。还原残余化学势χ的温度系数接近于零;因此稀释热非常小。稀释熵是正的，但很小。在前一篇论文中使用的统计热力学理论解释了多余体积的符号和大小。实验的偏摩尔熵比单独的组合贡献所允许的小得多。这一发现和Palmen最近的工作表明的小的负稀释焓主要来自于新理论的状态方程项。代表交换焓的参数X12是正的，并且很小，这应该是该系统所期望的。该理论很好地再现了观察到的χ随浓度的增加。测定了乙苯在10 ~ 90℃大气压下的热膨胀系数和热压系数。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Transactions of The Faraday Society

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