Measurements of the principal Hugoniots of dense gaseous deuterium−helium mixtures: Combined multi-channel optical pyrometry, velocity interferometry, and streak optical pyrometry measurements

The accurate hydrodynamic description of an event or system that addresses the equations of state, phase transitions, dissociations, ionizations, and compressions, determines how materials respond to a wide range of physical environments. To understand dense matter behavior in extreme conditions req...

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Bibliographic Details
Published inAIP advances Vol. 6; no. 10; pp. 105309 - 105309-10
Main Authors Li, Zhi-Guo, Chen, Qi-Feng, Gu, Yun-Jun, Zheng, Jun, Chen, Xiang-Rong
Format Journal Article
LanguageEnglish
Published Melville American Institute of Physics 01.10.2016
AIP Publishing LLC
Subjects
Deuterium
Diagnostic systems
Equations of state
Helium
Impedance matching
Interferometry
Measurement methods
Measurement techniques
Parameters
Phase transitions
Physical properties
Pyrometry
Spectrum analysis
Velocity
Velocity distribution
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Summary:The accurate hydrodynamic description of an event or system that addresses the equations of state, phase transitions, dissociations, ionizations, and compressions, determines how materials respond to a wide range of physical environments. To understand dense matter behavior in extreme conditions requires the continual development of diagnostic methods for accurate measurements of the physical parameters. Here, we present a comprehensive diagnostic technique that comprises optical pyrometry, velocity interferometry, and time-resolved spectroscopy. This technique was applied to shock compression experiments of dense gaseous deuterium–helium mixtures driven via a two-stage light gas gun. The advantage of this approach lies in providing measurements of multiple physical parameters in a single experiment, such as light radiation histories, particle velocity profiles, and time-resolved spectra, which enables simultaneous measurements of shock velocity, particle velocity, pressure, density, and temperature and expands understanding of dense high pressure shock situations. The combination of multiple diagnostics also allows different experimental observables to be measured and cross-checked. Additionally, it implements an accurate measurement of the principal Hugoniots of deuterium−helium mixtures, which provides a benchmark for the impedance matching measurement technique.
ISSN:2158-3226
2158-3226
DOI:10.1063/1.4966211