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arxiv: 2206.01637 · v2 · pith:JNHLNTG5new · submitted 2022-06-03 · ⚛️ physics.plasm-ph · cs.LG· physics.comp-ph

Unsupervised Discovery of Inertial-Fusion Plasma Physics using Differentiable Kinetic Simulations and a Maximum Entropy Loss Function

classification ⚛️ physics.plasm-ph cs.LGphysics.comp-ph
keywords plasmadifferentiablefunctioninertial-fusionkineticoptimizationsolverapplications
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Plasma supports collective modes and particle-wave interactions that leads to complex behavior in inertial fusion energy applications. While plasma can sometimes be modeled as a charged fluid, a kinetic description is useful towards the study of nonlinear effects in the higher dimensional momentum-position phase-space that describes the full complexity of plasma dynamics. We create a differentiable solver for the plasma kinetics 3D partial-differential-equation and introduce a domain-specific objective function. Using this framework, we perform gradient-based optimization of neural networks that provide forcing function parameters to the differentiable solver given a set of initial conditions. We apply this to an inertial-fusion relevant configuration and find that the optimization process exploits a novel physical effect that has previously remained undiscovered.

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