Thermal conductivity study of warm dense matter by differential heating on LCLS and Titan

M. Hill; A. Mckelvey; S. Jiang; R. Shepherd; S. Hau-Riege; H. Whitley; P. Sterne; S. Hamel; G. Collins; Y. Ping; C. Brown; E. Floyd; J. Fyrth; D. Hoarty; R. Hua; M. Bailly-Grandvaux; F. Beg; B. Cho; M. Kim; J. Lee; H. Lee; E. Galtier

Thermal conductivity study of warm dense matter by differential heating on LCLS and Titan

POSTER

Abstract

A differential heating platform has been developed for thermal conduction study, where a temperature gradient is induced and subsequent heat flow is probed by time-resolved diagnostics. Multiple experiment using this platform have been carried out at LCLS-MEC and Titan laser facilities for warm dense Al, Fe, amorphous carbon and diamond. Two single-shot time-resolved diagnostics are employed, SOP (streaked optical pyrometry) for surface temperature and FDI (Fourier Domain Interferometry) for surface expansion. Both diagnostics provided excellent data to constrain release equation-of-state (EOS) and thermal conductivity. Data sets with varying target thickness and comparison between simulations with different thermal conductivity models are presented.

^*This work was performed under DOE contract DE-AC52-07NA27344 with support from DOE OFES Early Career program and LLNL LDRD program.

Authors

M. Hill
- AWE
A. Mckelvey
- LLNL
S. Jiang
- LLNL
R. Shepherd
- LLNL
S. Hau-Riege
- LLNL
H. Whitley
- LLNL
P. Sterne
- LLNL
S. Hamel
- LLNL
G. Collins
- LLNL
Y. Ping
- LLNL
C. Brown
- AWE
E. Floyd
- AWE
J. Fyrth
- AWE
D. Hoarty
- AWE
R. Hua
- UCSD
M. Bailly-Grandvaux
- UCSD
F. Beg
- UCSD
B. Cho
- GIST
M. Kim
- GIST
J. Lee
- GIST
H. Lee
- SLAC
E. Galtier
- SLAC