# Nonlocal Heat Transport and Improved Target Design for X-ray Heating   Studies at X-ray Free Electron Lasers

**Authors:** Oliver R. Hoidn, Gerald T. Seidler

arXiv: 1704.04348 · 2018-01-24

## TL;DR

This paper models how nonlocal heat transport affects x-ray heating of targets at XFELs, demonstrating that multicomponent targets can significantly improve energy deposition and expand experimental capabilities.

## Contribution

It introduces three-dimensional simulations of x-ray energy deposition considering nonlocal heat transport, highlighting the benefits of nanoscale multicomponent targets for XFEL studies.

## Key findings

- Multicomponent targets enhance energy deposition by up to 100 times.
- Nonlocal heat transport is crucial for accurate modeling of x-ray heating.
- Nanoscale design improves the thermodynamic range and measurement capabilities.

## Abstract

The extremely high power densities and short durations of single pulses of x-ray free electron lasers (XFELs) have opened new opportunities in atomic physics, where complex excitation-relaxation chains allow for high ionization states in atomic and molecular systems, and in dense plasma physics, where XFEL heating of solid-density targets can create unique dense states of matter having temperatures on the order of the Fermi energy. We focus here on the latter phenomena, with special emphasis on the problem of optimum target design to achieve high x-ray heating into the warm dense matter (WDM) state. We report fully three-dimensional simulations of the incident x-ray pulse and the resulting multielectron relaxation cascade to model the spatial energy density deposition in multicomponent targets, with particular focus on the effects of nonlocal heat transport due to the motion of high energy photoelectrons and Auger electrons. We find that nanoscale high-Z/low-Z multicomponent targets can give much improved energy density deposition in lower-Z materials, with enhancements reaching a factor of 100. This has three important benefits. First, it greatly enlarges the thermodynamic parameter space in XFEL x-ray heating studies of lower-Z materials. Second, it allows the use of higher probe photon energies, enabling higher-information content X-ray diffraction (XRD) measurements such as in two-color XFEL operations. Third, while this is merely one step toward optimization of x-ray heating target design, the demonstration of the importance of nonlocal heat transport establishes important common ground between XFEL-based x-ray heating studies and more traditional laser plasma methods.

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Source: https://tomesphere.com/paper/1704.04348