Partition-of-unity flow-based solver for kinetic plasma simulations

Bowen Zhu; Jian Wu; Yuanbo Lu; Xingwen Li; Aici Qiu

doi:10.1016/j.jcp.2025.114608

Partition-of-unity flow-based solver for kinetic plasma simulations

Bowen Zhu
, Jian Wu
, Yuanbo Lu
, Xingwen Li
, Aici Qiu

School of Electrical Engineering

Xi'an Jiaotong University

Research output: Contribution to journal › Article › peer-review

Abstract

We introduce a novel flow-based solver for kinetic plasma simulations. Unlike Particle-in-Cell (PIC) methods that evolve particle weights ( f_id z ), our solver directly tracks the distribution function values ( f_i ) at specific phase-space points, or markers, providing an accurate point-wise representation. Unlike conventional semi-Lagrangian schemes, we maintain continuous marker trajectories along with the update of f_i and employ a Partition-of-Unity weighting to reconstruct macroscopic quantities without solving computationally expensive large linear systems. Validation shows our method achieves accuracy comparable to PIC while using 100 times fewer markers and reducing the computational wall time. The framework’s direct connection to Continuous Normalizing Flows opens promising avenues for developing hybrid physics-machine learning approaches.

Original language	English
Article number	114608
Journal	Journal of Computational Physics
Volume	549
DOIs	https://doi.org/10.1016/j.jcp.2025.114608
State	Published - 15 Mar 2026

Keywords

Continuous normalizing flows
Kinetic plasma simulation
Partition of unity weighting
Semi-lagrangian method

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10.1016/j.jcp.2025.114608

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title = "Partition-of-unity flow-based solver for kinetic plasma simulations",

abstract = "We introduce a novel flow-based solver for kinetic plasma simulations. Unlike Particle-in-Cell (PIC) methods that evolve particle weights ( fid z ), our solver directly tracks the distribution function values ( fi ) at specific phase-space points, or markers, providing an accurate point-wise representation. Unlike conventional semi-Lagrangian schemes, we maintain continuous marker trajectories along with the update of fi and employ a Partition-of-Unity weighting to reconstruct macroscopic quantities without solving computationally expensive large linear systems. Validation shows our method achieves accuracy comparable to PIC while using 100 times fewer markers and reducing the computational wall time. The framework{\textquoteright}s direct connection to Continuous Normalizing Flows opens promising avenues for developing hybrid physics-machine learning approaches.",

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AU - Zhu, Bowen

AU - Wu, Jian

AU - Lu, Yuanbo

AU - Li, Xingwen

AU - Qiu, Aici

PY - 2026/3/15

Y1 - 2026/3/15

N2 - We introduce a novel flow-based solver for kinetic plasma simulations. Unlike Particle-in-Cell (PIC) methods that evolve particle weights ( fid z ), our solver directly tracks the distribution function values ( fi ) at specific phase-space points, or markers, providing an accurate point-wise representation. Unlike conventional semi-Lagrangian schemes, we maintain continuous marker trajectories along with the update of fi and employ a Partition-of-Unity weighting to reconstruct macroscopic quantities without solving computationally expensive large linear systems. Validation shows our method achieves accuracy comparable to PIC while using 100 times fewer markers and reducing the computational wall time. The framework’s direct connection to Continuous Normalizing Flows opens promising avenues for developing hybrid physics-machine learning approaches.

AB - We introduce a novel flow-based solver for kinetic plasma simulations. Unlike Particle-in-Cell (PIC) methods that evolve particle weights ( fid z ), our solver directly tracks the distribution function values ( fi ) at specific phase-space points, or markers, providing an accurate point-wise representation. Unlike conventional semi-Lagrangian schemes, we maintain continuous marker trajectories along with the update of fi and employ a Partition-of-Unity weighting to reconstruct macroscopic quantities without solving computationally expensive large linear systems. Validation shows our method achieves accuracy comparable to PIC while using 100 times fewer markers and reducing the computational wall time. The framework’s direct connection to Continuous Normalizing Flows opens promising avenues for developing hybrid physics-machine learning approaches.

KW - Continuous normalizing flows

KW - Kinetic plasma simulation

KW - Partition of unity weighting

KW - Semi-lagrangian method

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DO - 10.1016/j.jcp.2025.114608

M3 - 文章

AN - SCOPUS:105025980425

SN - 0021-9991

VL - 549

JO - Journal of Computational Physics

JF - Journal of Computational Physics

M1 - 114608

ER -

Partition-of-unity flow-based solver for kinetic plasma simulations

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