确定振动热容量和热膨胀系数及其在玻璃-液体转变时的变化。

Determining vibrational heat capacity and thermal expansivity and their change at glass-liquid transition.

作者信息

Johari G P

机构信息

Department of Materials Science and Engineering, McMaster University, Hamilton, Ontario L8S 4L7, Canada.

出版信息

J Chem Phys. 2007 Mar 21;126(11):114901. doi: 10.1063/1.2711206.

DOI:10.1063/1.2711206

Abstract

The vibrational parts of a liquid's heat capacity Cp and thermal expansion coefficient alpha may be determined from dynamic measurements. The Cp data for Pd40Ni40P20 and 0.4 Ca(NO3)(2).0.6 KNO3 have been analyzed accordingly, and it is found that change in the vibrational part at liquid-glass transformation is negligible. Analysis for alpha of poly(styrene) leads to the same conclusion. There is no discontinuity in the vibrational parts of Cp and alpha on structural unfreezing in the Tg range, and hence the change in Cp and alpha at Tg is almost entirely due to change in the configurational part. Crystallization decreases the vibrational part not because the molecular mobility is lost but because the density increases.

摘要

液体比热容(Cp)和热膨胀系数(\alpha)的振动部分可通过动态测量来确定。已据此分析了(Pd40Ni40P20)和(0.4Ca(NO3)_2.0.6KNO3)的(Cp)数据，发现液-玻璃转变时振动部分的变化可忽略不计。对聚苯乙烯的(\alpha)分析也得出相同结论。在玻璃化转变温度（(Tg)）范围内，结构解冻时(Cp)和(\alpha)的振动部分没有不连续性，因此(Tg)处(Cp)和(\alpha)的变化几乎完全归因于构型部分的变化。结晶会降低振动部分，不是因为分子流动性丧失，而是因为密度增加。

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