Shock behavior of materials.

10.1063/5.0085292 85 R. Knepper, S. Rupper, S. DeJong, M. P. Marquez, D. E. Kittell, R. L. Schmitt, and A. S. Tappan, "Investigating growth to detonation in vapor-deposited hexanitrostilbene and pentaerythritol tetranitrate films using high-throughput methods", J. Appl. Phys. Such investigations can be applied to a wide range of materials such as pure metals,[[23], [25], [27]] steels,[29] other metallic alloys[[15], [30], [32]] including additively manufactured alloys,[[34]] ceramics,[36] polymers,[37] energetic materials,[38] or nanoporous materials.[[39]] B. Equation of state and phase transitions under shock compression I In situ i x-ray diffraction (XRD) has been used to investigate the occurrence and nature of phase transitions upon shock compression at large laser facilities, synchrotron, and x-ray free electron lasers. 10.1063/5.0076869 52 P. E. Specht, W. Reinhart, and C. Scott Alexander, "Measurement of the Hugoniot and shock-induced phase transition stress in wrought 17-4 PH H1025 stainless steel", J. Appl. Phys. R. Armstrong, H. B. Radousky, R. A. Austin, O. Tschauner, S. Brown, A. E. Gleason, N. Goldman, E. Granados, P. Grivickas, N. Holtgrewe, M. P. Kroonblawd, H. J. Lee, S. Lobanov, B. Nagler, I. Nam, V. Prakapenka, C. Prescher, E. J. Reed, E. Stavrou, P. Walter, A. F. Goncharov, and J. L. Belof, "Highly ordered graphite (HOPG) to hexagonal diamond (lonsdaleite) phase transition observed on picosecond time scales using ultrafast x-ray diffraction", J. Appl. Phys. [Extracted from the article]