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Autores principales: Walker, Jack, Wallace, Emma, Clark, Ken, van Anders, Greg, Wright, Alex
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2512.11257
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author Walker, Jack
Wallace, Emma
Clark, Ken
van Anders, Greg
Wright, Alex
author_facet Walker, Jack
Wallace, Emma
Clark, Ken
van Anders, Greg
Wright, Alex
contents The Scintillating Bubble Chamber collaboration is searching for Weakly Interacting Massive Particles using a novel bubble chamber with intended thresholds as low as 100eV. Existing molecular dynamics simulations of bubble formation in bubble chambers were conducted with non-scintillating target materials and therefore do not account for the energy transfer to photons or time-delayed releases that occur in atomic de-excitation. In this study, we use the HOOMD-blue molecular dynamics framework to simulate bubble formation in liquid argon, including photon creation, ionization, and direct nuclear recoils. A multi-stage bubble growth process similar to that reported in the literature was observed. When comparing simulated thresholds with and without scintillation effects, we found that scintillation raises the average energy required to form a bubble by a factor of 2.16. This is larger than the fraction of energy lost to photon creation, and demonstrates that energy stored in excited molecular states with lifetimes longer than the rapid growth phase of nucleation (~250 ps) does not contribute significantly to bubble formation. This conclusion was further supported by simulations showing increased bubble nucleation thresholds when the excited molecular state lifetimes were increased, even under identical thermodynamic conditions.
format Preprint
id arxiv_https___arxiv_org_abs_2512_11257
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Molecular Dynamics Simulations of Bubble Nucleation in a Liquid-Noble Scintillator
Walker, Jack
Wallace, Emma
Clark, Ken
van Anders, Greg
Wright, Alex
High Energy Physics - Experiment
Chemical Physics
Computational Physics
The Scintillating Bubble Chamber collaboration is searching for Weakly Interacting Massive Particles using a novel bubble chamber with intended thresholds as low as 100eV. Existing molecular dynamics simulations of bubble formation in bubble chambers were conducted with non-scintillating target materials and therefore do not account for the energy transfer to photons or time-delayed releases that occur in atomic de-excitation. In this study, we use the HOOMD-blue molecular dynamics framework to simulate bubble formation in liquid argon, including photon creation, ionization, and direct nuclear recoils. A multi-stage bubble growth process similar to that reported in the literature was observed. When comparing simulated thresholds with and without scintillation effects, we found that scintillation raises the average energy required to form a bubble by a factor of 2.16. This is larger than the fraction of energy lost to photon creation, and demonstrates that energy stored in excited molecular states with lifetimes longer than the rapid growth phase of nucleation (~250 ps) does not contribute significantly to bubble formation. This conclusion was further supported by simulations showing increased bubble nucleation thresholds when the excited molecular state lifetimes were increased, even under identical thermodynamic conditions.
title Molecular Dynamics Simulations of Bubble Nucleation in a Liquid-Noble Scintillator
topic High Energy Physics - Experiment
Chemical Physics
Computational Physics
url https://arxiv.org/abs/2512.11257