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Development of the Glassy State of Benzophenone and Effect of Heating Rate from the Glassy State on Solidification

Published online by Cambridge University Press:  10 February 2011

Paul E. Thoma  and
John J. Boehm
Paul E. Thoma
Affiliation:
Johnson Controls, Inc., Central Research, P.O. Box 591, Milwaukee, WI 53201–0591, USA
John J. Boehm
Affiliation:
Johnson Controls, Inc., Central Research, P.O. Box 591, Milwaukee, WI 53201–0591, USA
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Abstract

Benzophenone supercools to a glass when cooled to −100°C. In fact, it is difficult to freeze benzophenone on cooling. In this investigation, the effect of cooling rate and the minimum cooling rate to obtain benzophenone as a glass is determined. From the glassy state, the influence of heating rate on the solidification temperature of benzophenone is determined. When heated at 3°C/min., solidification starts at about −29°C. Upon additional heating, melting usually starts at about +24°C, which is 23°C lower than the solid equilibrium structure melting temperature of 47°C. Occasionally the solid that forms at about −29°C undergoes a solid state phase transformation at about +22°C, when heated at 3°C/min. If this solid state phase transformation occurs, then the solid benzophenone starts to melt at 47°C. When solid benzophenone with the equilibrium structure is cooled to −100°C, no solid state phase transformation occurs. It appears that the structure that solidifies at −29°C is metastable.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 455: Symposium T – Glasses and Glass Formers–Current Issues , 1996 , 429
Copyright
Copyright © Materials Research Society 1997

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References

REFERENCES

1. Thoma, P.E., “A Mechanism for Supercooling in Organic Liquids”, Thermodynamics and Kinetics of Phase Transformations, Materials Research Society Symposium in Boston, MA (Nov. 27 - Dec. 1, 1995), Im, J.S., Park, B., Greer, A.L. and Stephenson, G.B. Eds. (Materials Research Society, Pittsburgh, PA, USA, Vol. 398, 1996) pp. 8792.Google Scholar
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