Oxford Centre for High Energy Density Science (OxCHEDS)

Data-efficient learning of exchange-correlation functionals with differentiable DFT

Machine Learning: Science and Technology IOP Publishing 7:2 (2026) 025001-025001

Authors:

Antonius von Strachwitz, Karim K Alaa El-Din, Ana CC Dutra, Sam M Vinko

Abstract:

Abstract Machine learning (ML) density functional approximations (DFAs) have seen a lot of interest in recent years, often being touted as the replacement for well-established non-empirical DFAs, which still dominate the field. Although highly accurate, ML-DFAs typically rely on large amounts of data, are computationally expensive, and fail to generalize beyond their training domain. In this work we show that differentiable DFT with Kohn–Sham regularization can be used to accurately capture the behavior of known local density approximations from small sets of synthetic data without using localized density information. At the same time our analysis shows a strong dependence of the learning on both the amount and type of data as well as on model initialization. By enabling accurate learning from sparse energy data, this approach paves the way towards the development of custom ML-DFAs trained directly on limited experimental or high-level quantum chemistry datasets.

Probing keV mass QCD axions with the SACLA X-ray free electron laser

(2026)

Authors:

Charles Heaton, Jack WD Halliday, Taito Osaka, Ichiro Inoue, Sifei Zhang, Ahmed Alsulami, Joshua TY Chu, Mila Fitzgerald, Takaki Hatsui, Motoaki Nakatsutsumi, Haruki Nishino, Atsushi O Tokiyasu, Robert Bingham, Subir Sarkar, Gianluca Gregori

Modeling partially ionized dense plasma using wavepacket molecular dynamics

Physical Review E American Physical Society (APS) (2026)

Measurement of ion acceleration and diffusion in a laser-driven magnetized plasma

Nature Communications Nature Research (2026)

Authors:

JTY Chu, JWD Halliday, C Heaton, K Moczulski, A Blazevic, D Schumacher, M Metternich, H Nazary, CD Arrowsmith, AR Bell, KA Beyer, AFA Bott, T Campbell, E Hansen, DQ Lamb, F Miniati, P Neumayer, CAJ Palmer, B Reville, A Reyes, S Sarkar, A Scopatz, C Spindloe, CB Stuart, H Wen, P Tzeferacos, R Bingham, G Gregori

Abstract:

Here we present results from an experiment performed at the GSI Helmholtz Center for Heavy Ion Research. A mono-energetic beam of chromium ions with initial energies of  ~ 450 MeV was fired through a magnetized interaction region formed by the collision of two counter-propagating laser-ablated plasma jets. While laser interferometry revealed the absence of strong fluid-scale turbulence, acceleration and diffusion of the beam ions was driven by wave-particle interactions. A possible mechanism is particle acceleration by electrostatic, short scale length kinetic turbulence, such as the lower-hybrid drift instability.

Time-embedded convolutional neural networks for modeling plasma heat transport

Physical Review E American Physical Society (APS) 113:3 (2026) 035303

Authors:

Mufei Luo, Charles Heaton, Yizhen Wang, Daniel Plummer, Mila Fitzgerald, Francesco Miniati, Sam M Vinko, Gianluca Gregori

Abstract:

We introduce a time-embedded convolutional neural network (TCNN) for modeling spatiotemporal heat transport in plasmas, particularly under strongly nonlocal conditions. In our earlier work, the Luciani-Mora-Virmont (LMV) Informed Neural Network (LINN) (Luo , ) combined prior knowledge from the LMV model with kinetic Particle-in-Cell (PIC) data to improve kernel-based heat-flux predictions. While effective under moderately nonlocal conditions, LINN produced physically inconsistent kernels in strongly time-dependent regimes due to its reliance on the quasistationary LMV formulation. To overcome this limitation, TCNN is designed to capture the coupled evolution of both the normalized heat flux and the characteristic nonlocality parameter using a unified neural architecture informed by underlying physical principles. Trained on fully kinetic PIC simulations, TCNN accurately reproduces nonlocal dynamics across a broad range of collisionalities. Our results demonstrate that the combination of time modulation, coupled prediction, and convolutional depth significantly enhances predictive performance, offering a data-driven yet physically consistent framework for multiscale plasma transport problems.