Litcius/Paper detail

Modeling laser-driven ion acceleration with deep learning

B. Z. Djordjević, A. Kemp, J. Kim, Raspberry Simpson, S. C. Wilks, T. Ma, D. Mariscal

2021Physics of Plasmas36 citationsDOIOpen Access PDF

Abstract

Developments in machine learning promise to ameliorate some of the challenges of modeling complex physical systems through neural-network-based surrogate models. High-intensity, short-pulse lasers can be used to accelerate ions to mega-electronvolt energies, but to model such interactions requires computationally expensive techniques such as particle-in-cell simulations. Multilayer neural networks allow one to take a relatively sparse ensemble of simulations and generate a surrogate model that can be used to rapidly search the parameter space of interest. In this work, we created an ensemble of over 1,000 simulations modeling laser-driven ion acceleration and developed a surrogate to study the resulting parameter space. A neural-network-based approach allows for rapid feature discovery not possible for traditional parameter scans given the computational cost. A notable observation made during this study was the dependence of ion energy on the pre-plasma gradient length scale. While this methodology harbors great promise for ion acceleration, it has ready application to all topics in which large-scale parameter scans are restricted by significant computational cost or relatively large, but sparse, domains.

Topics & Concepts

AccelerationPhysicsArtificial neural networkParameter spaceIonArtificial intelligenceScale (ratio)Machine learningSurrogate modelComputational physicsComputer scienceStatistical physicsClassical mechanicsQuantum mechanicsMathematicsStatisticsLaser-Plasma Interactions and DiagnosticsLaser-induced spectroscopy and plasmaGamma-ray bursts and supernovae