High pressure deep-release impact experiments on high density and ultra-high molecular weight polyethylene

The high pressure dynamic response of polymers is important to a wide variety of applications. The details of compressibility and reactivity can have a large effect on overall behaviors of dynamic systems even when polymers are used in small amounts. Polyethylene is of broad interest for a variety o...

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Bibliographic Details
Main Authors: Hooks, D. E., Lang, J. M., Coe, J. D., Dattelbaum, D. M.
Format: Conference Proceeding
Language:English
Subjects:
Chemical composition
Compressibility
Density
Dynamic response
Equations of state
Molecular weight
Organic chemistry
Plate impact tests
Polyethylene
Ultra high molecular weight polyethylene
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Summary:The high pressure dynamic response of polymers is important to a wide variety of applications. The details of compressibility and reactivity can have a large effect on overall behaviors of dynamic systems even when polymers are used in small amounts. Polyethylene is of broad interest for a variety of applications, as an ingredient and as a pure material. It is also of significant interest as a model system to understand the correlating effects of polymer dynamics in a material with a relatively simple chemical composition that can have highly varied properties through the alteration of molecular weight and associated crystallinity of the material. Although a variety of Hugoniot and dynamic information is available for polyethylene, it is a challenge to obtain information on the product equation of state at pressures high enough to achieve decomposition. Following recent successes in producing deep release states in compressed epoxy material, a series of plate impact experiments was performed in the same configuration on high density and ultra-high molecular weight polyethylene at pressures where there is only limited Hugoniot data. The experimental wave profiles are presented and the Hugoniot states are compared to previous results. In ongoing work, the release profiles are intended to calibrate a product equation of state.
ISSN:0094-243X
1551-7616
DOI:10.1063/1.5044774