English

BRICKS: Compositional Neural Markov Kernels for Zero-Shot Radiation-Matter Simulation

Machine Learning 2026-05-08 v1 High Energy Physics - Phenomenology

Abstract

We introduce a new strategy for compositional neural surrogates for radiation-matter interactions, a key task spanning domains from particle physics through nuclear and space engineering to medical physics. Exploiting the locality and the Markov nature of particle interactions, we create a \emph{next-particle prediction} kernel using hybrid discrete-continuous transformer models based on Riemannian Flow Matching on product manifolds. The model generates variable-sized typed sets of particles and radiation side effects that are the result of the interaction of an incident particle with a material volume. The resulting kernel can be composed to simulate unseen large-scale material distributions in a zero-shot manner. Unlike mechanistic simulators, our model is designed to be differentiable, provides tractable likelihoods for future downstream applications. A significant computational speed-up on GPU compared to CPU-bound mechanistic simulation is observed for single-kernel execution. We evaluate the model at the kernel level and demonstrate predictive stability over multi-round autoregressive rollouts. We additionally release a novel 20M-event radiation-matter interaction dataset for further research.

Keywords

Cite

@article{arxiv.2605.06591,
  title  = {BRICKS: Compositional Neural Markov Kernels for Zero-Shot Radiation-Matter Simulation},
  author = {Richard Hildebrandt and Evangelos Kourlitis and Baran Hashemi and Manuel Bünstorf and Thierry Meyer and Nikola Boskov and Michael Kagan and Dan Rosenbaum and Sanmay Ganguly and Lukas Heinrich},
  journal= {arXiv preprint arXiv:2605.06591},
  year   = {2026}
}

Comments

10 pages, 5 figures

R2 v1 2026-07-01T12:55:38.840Z