Heat capacity and glass transition thermodynamics for zinc chloride. A failure of the first Davies-Jones relation for dTg/dP

C. A. Angell; E. Williams; K. J. Rao; J. C. Tucker

doi:10.1021/j100518a011

Heat capacity and glass transition thermodynamics for zinc chloride. A failure of the first Davies-Jones relation for dT_g/dP

C. A. Angell, E. Williams, K. J. Rao, J. C. Tucker

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Abstract

Measurement of the heat capacities of the liquid, glass, and crystal (α-polymorph) forms of ZnCl₂, and of the pressure dependence of the glass transition temperature, are reported. The excess heat capacity, and the temperature dependence of the viscosity as well, may be described using two-parameter equations from the bond-lattice model. The glass transition temperature at a given pressure is independent, within experimental error, of the pressure-temperature history of the sample. The observed pressure dependence, however, is only half the value predicted from the changes in heat capacity and expansion coefficient at T_g by the Davies-Jones equation. This uncommon failure of the equation is attributed to a small ΔC_p associated with the network structure of zinc chloride.

Original language	English (US)
Pages (from-to)	238-243
Number of pages	6
Journal	Journal of physical chemistry
Volume	81
Issue number	3
DOIs	https://doi.org/10.1021/j100518a011
State	Published - Jan 1 1977
Externally published	Yes

ASJC Scopus subject areas

General Engineering
Physical and Theoretical Chemistry

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abstract = "Measurement of the heat capacities of the liquid, glass, and crystal (α-polymorph) forms of ZnCl2, and of the pressure dependence of the glass transition temperature, are reported. The excess heat capacity, and the temperature dependence of the viscosity as well, may be described using two-parameter equations from the bond-lattice model. The glass transition temperature at a given pressure is independent, within experimental error, of the pressure-temperature history of the sample. The observed pressure dependence, however, is only half the value predicted from the changes in heat capacity and expansion coefficient at Tg by the Davies-Jones equation. This uncommon failure of the equation is attributed to a small ΔCp associated with the network structure of zinc chloride.",

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T1 - Heat capacity and glass transition thermodynamics for zinc chloride. A failure of the first Davies-Jones relation for dTg/dP

AU - Angell, C. A.

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AU - Rao, K. J.

AU - Tucker, J. C.

PY - 1977/1/1

Y1 - 1977/1/1

N2 - Measurement of the heat capacities of the liquid, glass, and crystal (α-polymorph) forms of ZnCl2, and of the pressure dependence of the glass transition temperature, are reported. The excess heat capacity, and the temperature dependence of the viscosity as well, may be described using two-parameter equations from the bond-lattice model. The glass transition temperature at a given pressure is independent, within experimental error, of the pressure-temperature history of the sample. The observed pressure dependence, however, is only half the value predicted from the changes in heat capacity and expansion coefficient at Tg by the Davies-Jones equation. This uncommon failure of the equation is attributed to a small ΔCp associated with the network structure of zinc chloride.

AB - Measurement of the heat capacities of the liquid, glass, and crystal (α-polymorph) forms of ZnCl2, and of the pressure dependence of the glass transition temperature, are reported. The excess heat capacity, and the temperature dependence of the viscosity as well, may be described using two-parameter equations from the bond-lattice model. The glass transition temperature at a given pressure is independent, within experimental error, of the pressure-temperature history of the sample. The observed pressure dependence, however, is only half the value predicted from the changes in heat capacity and expansion coefficient at Tg by the Davies-Jones equation. This uncommon failure of the equation is attributed to a small ΔCp associated with the network structure of zinc chloride.

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Heat capacity and glass transition thermodynamics for zinc chloride. A failure of the first Davies-Jones relation for dT_g/dP

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