Machine-learned collision operators from Particle-in-Cell simulations
ORAL
Abstract
Computational plasma physics has seen significant advances in the ability to model nonlinear plasma dynamics from first principles. However, capturing the complex multi-scale dynamics of plasmas, especially in non-equilibrium and strongly coupled regimes, remains challenging. One of such challenges is the development of collisional operators that capture the macroscopic dynamics in regimes where existing analytical theory is expected to fail.
In this talk, we will highlight how differentiable simulators, coupled with machine learning algorithms and self-consistent Particle in Cell (PIC) data, can be used to efficiently learn collision operators [1]. As a test case, we will focus on extracting the collision operator for an electromagnetic PIC code and compare the retrieved operator against existing theory [2,3]. We will conclude by illustrating how, using the same simulation tools, one can shed light on the nature of collisions in strongly coupled regimes and, in the future, elucidate how collisional operators are modified in strongly coupled, relativistic, and far-from-thermodynamic-equilibrium conditions.
[1] D. Carvalho et al, in preparation (2025)
[2] A. B. Langdon. Proc. 4th Conference on Numerical Simulation of Plasmas (1970), pp. 467–495
[3] H. Okuda and C. K. Birdsall, Phys. Fluids 13.8 (1970), pp. 2123–2134
In this talk, we will highlight how differentiable simulators, coupled with machine learning algorithms and self-consistent Particle in Cell (PIC) data, can be used to efficiently learn collision operators [1]. As a test case, we will focus on extracting the collision operator for an electromagnetic PIC code and compare the retrieved operator against existing theory [2,3]. We will conclude by illustrating how, using the same simulation tools, one can shed light on the nature of collisions in strongly coupled regimes and, in the future, elucidate how collisional operators are modified in strongly coupled, relativistic, and far-from-thermodynamic-equilibrium conditions.
[1] D. Carvalho et al, in preparation (2025)
[2] A. B. Langdon. Proc. 4th Conference on Numerical Simulation of Plasmas (1970), pp. 467–495
[3] H. Okuda and C. K. Birdsall, Phys. Fluids 13.8 (1970), pp. 2123–2134
*This work was supported by the FCT—Fundação para a Ciência e Tecnologia, I.P. under the Project No. 2022.02230.PTDC (X-MASER), PhD Fellowship Grant 2022.13261.BD and has received funding from the European Union's H2020 programme through the Project IMPULSE (Grant Agreement No. 871161). DC research visit to the UCLA was sponsored by a Fulbright Grant for Research with the support of FCT and by the Mani L. Bhaumik Institute for Theoretical Physics at UCLA. Simulations and machine learning workloads were performed in Deucalion (Portugal) within the FCT I.P project 2024.11062.CPCA.A3 and 2024.12682.CPCA.A1, and EuroHPC proposal No. EHPC-DEV-2025D02-069.
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Presenters
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Diogo D Carvalho
- GoLP/IPFN, Instituto Superior Técnico, Universidade de Lisboa