On the Dynamic Compression of Elements: Phase Transition Lowering in Dynamically-Compressed Silicon

Despite being the subject of numerous shock compression studies, the behavior of silicon under dynamic loading is vigorously debated [1-4]. The few studies that combine shock compression and X-ray diffraction have exclusively focused on "normal" X-ray geometry whereby X-rays are collected along the shock propagation direction, consequently sampling numerous strain states at once, and hence greatly complicating both phase identification and studies of phase transition kinetics.[5] Here, we present a novel setup to perform in situ X-ray diffraction studies perpendicular to the shock propagation direction at the Matter in Extreme Conditions end station at Linac Coherent Light Source, SLAC. Combining the extremely bright, micro-focused X-ray beam available at the LCLS with a nanosecond laser driver, we unambiguously characterize of the complex multi-wave shock response in silicon for the first time. We further combine this platform with simultaneous imaging with diffraction from shock compressed germanium.

Reference
[1] Graham et al., JPCS, 27, 9 (1966)
[2] Turneaure & Gupta, APL, 90, 051905 (2007)
[3] Colburn et al., JAP, 43, 5007 (1972)
[4] Gust & Royce, JAP, 42, 1897 (1971)
[5] Turneaure et al., PRL, 121, 135701 (2018)