Title: Measurements of Picosecond Energy Equilibration in Isochorically Heated Materials

In this Final Report we present the results of our DOE/FES-sponsored research on rapidly heated materials. The research focused on the details of picosecond energy equilibration and material response to isochoric heating by relativistic (or “hot”) electrons. The major goal was to improve the understanding of these processes by making time-resolved extreme ultraviolet (XUV) measurements of ultrafast energy deposition and blast-wave formation for testing impulsive-heating models in extreme thermodynamic conditions. Major achievements of the project include the design, fabrication, deployment, and use of two XUV spectrometers on the Multi-Terawatt (MTW) Laser System at the University of Rochester’s Laboratory for Laser Energetics. One of the spectrometers is coupled to an x-ray charge-coupled device (CCD) for time-integrated measurements; the other is coupled to an ultrafast x-ray streak camera for time-resolved measurements. Working together, these instruments provide absolutely calibrated data on the emitted XUV spectrum from an isochoric heated target. The new diagnostic system was used to measure and infer the time-resolved rear-surface temperature and density for different target materials and different target-interaction conditions. Experiments with laser-heated metal foils measured the ultrafast dynamics and energy deposition from hot electrons into plasma heating and blast-wave formation. The blast wave was observed emerging from the rear surface of the laser-irradiated target. The time between the prompt emission (electron-driven x-ray emission) and the blast-wave arrival was used to estimate the energy deposition into the wave. The data are consistent with a Sedov–Taylor blast wave, with energy transfer from the laser to the blast of up to 20 mJ. The data represent the first quantitative assessment of the blast-wave energy in a metal following heating by a short burst of high-intensity laser-generated hot electrons. The funding from this grant provided significant opportunities for training and professional development. The grant supported or partially supported a graduate student, a postdoctoral research associate, and a senior staff scientist. This support included bringing together a dedicated group of individuals with a niche set of experimental and theoretical skills for studying advanced material properties experiments and ultrafast radiation conditions. The team dynamic fostered training and knowledge transfer across the whole spectrum of research activities through shared experiences in advanced laboratory techniques, data analysis, modeling, and the development of new ideas, techniques, presentations, and publications. The results of this work, which significantly improve the understanding of rapid energy deposition in solid matter, have been widely disseminated to communities of interest through invited talks, contributed talks, and peer-reviewed journals.