English

Optimizing Charge Transport Simulation for Hybrid Pixel Detectors

Instrumentation and Detectors 2024-10-23 v3

Abstract

To enhance the spatial resolution of the M\"ONCH 25 \textmu m pitch hybrid pixel detector, deep learning models have been trained using both simulation and measurement data. Challenges arise when comparing simulation-based deep learning models to measurement-based models for electrons, as the spatial resolution achieved through simulations is notably inferior to that from measurements. Discrepancies are also observed when directly comparing X-ray simulations with measurements, particularly in the spectral output of single pixels. These observations collectively suggest that current simulations require optimization. To address this, the dynamics of charge carriers within the silicon sensor have been studied using Monte Carlo simulations, aiming to refine the charge transport modeling. The simulation encompasses the initial generation of the charge cloud, charge cloud drift, charge diffusion and repulsion, and electronic noise. The simulation results were validated with measurements from the M\"ONCH detector for X-rays, and the agreement between measurements and simulations was significantly improved by accounting for the charge repulsion.

Keywords

Cite

@article{arxiv.2407.20841,
  title  = {Optimizing Charge Transport Simulation for Hybrid Pixel Detectors},
  author = {X. Xie and R. Barten and A. Bergamaschi and B. Braham and M. Brückner and M. Carulla and R. Dinapoli and S. Ebner and K. Ferjaoui and E. Fröjdh and D. Greiffenberg and S. Hasanaj and J. Heymes and V. Hinger and T. King and P. Kozlowski and C. Lopez-Cuenca and D. Mezza and K. Moustakas and A. Mozzanica and K. A. Paton and C. Ruder and B. Schmitt and P. Sieberer and D. Thattil and J. Zhang},
  journal= {arXiv preprint arXiv:2407.20841},
  year   = {2024}
}

Comments

Prepared for submission to JINST as a proceeding for 25th International Workshops on Radiation Imaging Detectors

R2 v1 2026-06-28T17:58:12.145Z