Physics Informed Neural Networks for design optimisation of diamond particle detectors for charged particle fast-tracking at high luminosity hadron colliders

Alessandro Bombini; Alessandro Rosa; Clarissa Buti; Giovanni Passaleva; Lucio Anderlini

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Physics Informed Neural Networks for design optimisation of diamond particle detectors for charged particle fast-tracking at high luminosity hadron colliders

by Alessandro Bombini, Alessandro Rosa, Clarissa Buti, Giovanni Passaleva, Lucio Anderlini

Submission summary

Authors (as registered SciPost users):

Alessandro Bombini

Submission information
Preprint Link:	https://arxiv.org/abs/2509.21123v1 (pdf)
Code repository:	https://baltig.infn.it/bombini/diamond-eucaifcon25.git
Data repository:	https://chnet-001.fi.infn.it:8443/s/T9MDJhAZJN2OJKA
Date submitted:	Sept. 26, 2025, 10:13 a.m.
Submitted by:	Alessandro Bombini
Submitted to:	SciPost Physics Proceedings
Proceedings issue:	The 2nd European AI for Fundamental Physics Conference (EuCAIFCon2025)

Ontological classification
Academic field:	Physics
Specialties:	High-Energy Physics - Experiment
Approaches:	Experimental, Computational

Abstract

Future high-luminosity hadron colliders demand tracking detectors with extreme radiation tolerance, high spatial precision, and sub-nanosecond timing. 3D diamond pixel sensors offer these capabilities due to diamond's radiation hardness and high carrier mobility. Conductive electrodes, produced via femtosecond IR laser pulses, exhibit high resistivity that delays signal propagation. This effect necessitates extending the classical Ramo-Shockley weighting potential formalism. We model the phenomenon through a 3rd-order, 3+1D PDE derived as a quasi-stationary approximation of Maxwell's equations. The PDE is solved numerically and coupled with charge transport simulations for realistic 3D sensor geometries. A Mixture-of-Experts Physics-Informed Neural Network, trained on Spectral Method data, provides a meshless solver to assess timing degradation from electrode resistance.

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Reports on this Submission

Report #1 by Anonymous (Referee 1) on 2025-11-7 (Invited Report)

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This is a very well-written manuscript. Since it's very short (conference proceedings), there is not much to comment. I am not a very big expert on this topic, however the presented problem of diamond detector optimisation and the results are very clear. The strength is that the results show not only simulations but also application to the real experiment.

Since this is based on a talk from the EuCAIFCon, it was already discussed within the community and I can recommend the publication as is. Language-wise it's written in a very good English.

Recommendation

Publish (easily meets expectations and criteria for this Journal; among top 50%)

validity: high
significance: high
originality: high
clarity: high
formatting: perfect
grammar: perfect

SciPost Submission Page

Physics Informed Neural Networks for design optimisation of diamond particle detectors for charged particle fast-tracking at high luminosity hadron colliders

by Alessandro Bombini, Alessandro Rosa, Clarissa Buti, Giovanni Passaleva, Lucio Anderlini

Submission summary

Abstract

Current status:

Reports on this Submission

Report #1 by Anonymous (Referee 1) on 2025-11-7 (Invited Report)

Report

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