What type of study is this?

This is a Quantitative Study study.

October 16, 2025Open Access

Fate of an impurity strongly interacting with a thermal Bose gas

Key Points

Narrowing of impurity spectra occurs with increasing temperature for strong interactions, indicating altered dynamics.
The impurity energy shift is suppressed as temperatures rise, reflecting complex interactions with the thermal bath.
Many-body effects influence the system's behavior nearing critical condensation temperature, challenging classical expectations.
The study's findings align well with the ideal Bose polaron theory, showcasing the relevance of theoretical models.

Abstract

We spectroscopically study mobile impurities immersed in a homogeneous bosonic bath (a box-trapped Bose gas), varying the bath temperature and the strength of impurity-bath interactions. We compare our results to those for a quasipure Bose-Einstein condensate (BEC), and find that for strong impurity-bath interactions, the spectra narrow with increasing temperature, while the impurity energy shift is suppressed. Near the critical temperature for condensation, many-body effects still play an important role, and only for a nondegenerate bath, the system approaches the classical Boltzmann-gas behavior. The key spectral features are reproduced within the theory of an ideal Bose polaron.

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Cite This Study

Etrych et al. (Fri,) studied this question.

synapsesocial.com/papers/68f12bfb2107091eab27a360 https://doi.org/https://doi.org/10.48550/arxiv.2508.06493

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