Does it matter? A more careful treatment of density fluctuations in 21-cm simulations
The cosmological 21-cm signal is sourced from hyperfine transitions in neutral hydrogen atoms. Yet, although hydrogen atoms belong to the sub-class of baryonic matter, it is customary to simplify their treatment and analyze the 21-cm signal as if all the matter in the Universe was in the form of col...
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| creator | Flitter, Jordan Libanore, Sarah Kovetz, Ely D |
| description | The cosmological 21-cm signal is sourced from hyperfine transitions in
neutral hydrogen atoms. Yet, although hydrogen atoms belong to the sub-class of
baryonic matter, it is customary to simplify their treatment and analyze the
21-cm signal as if all the matter in the Universe was in the form of
collisionless cold dark matter (CDM). This is usually done by evolving the
density field via a scale-independent growth factor (SIGF). In this work, we
separate the baryons from CDM and evolve the two species with a proper
scale-dependent growth factor (SDGF). By incorporating the SDGF in the
21cmFirstCLASS code, we demonstrate the effect that baryons and CDM have on the
21-cm signal at the linear dark ages epoch and the subsequent non-linear epochs
of cosmic dawn and reionization. Our analysis shows that the baryonic nature of
hydrogen cannot be ignored during the dark ages, and that non-linear effects in
density-field evolution must be accounted for after stars have formed.
Furthermore, we discuss how the 21-cm signal is modified at lower redshifts,
where ground-based 21-cm interferometers are mostly sensitive, due to the
choice of working with either the "linear" or "non-linear" matter over-density
(that is, the over-density as computed from linear perturbation theory, and
non-linear perturbation theory, respectively) in the extended Press-Schechter
formalism. Our code is publicly available at
https://github.com/jordanflitter/21cmFirstCLASS. |
| doi_str_mv | 10.48550/arxiv.2411.00089 |
| format | Article |
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neutral hydrogen atoms. Yet, although hydrogen atoms belong to the sub-class of
baryonic matter, it is customary to simplify their treatment and analyze the
21-cm signal as if all the matter in the Universe was in the form of
collisionless cold dark matter (CDM). This is usually done by evolving the
density field via a scale-independent growth factor (SIGF). In this work, we
separate the baryons from CDM and evolve the two species with a proper
scale-dependent growth factor (SDGF). By incorporating the SDGF in the
21cmFirstCLASS code, we demonstrate the effect that baryons and CDM have on the
21-cm signal at the linear dark ages epoch and the subsequent non-linear epochs
of cosmic dawn and reionization. Our analysis shows that the baryonic nature of
hydrogen cannot be ignored during the dark ages, and that non-linear effects in
density-field evolution must be accounted for after stars have formed.
Furthermore, we discuss how the 21-cm signal is modified at lower redshifts,
where ground-based 21-cm interferometers are mostly sensitive, due to the
choice of working with either the "linear" or "non-linear" matter over-density
(that is, the over-density as computed from linear perturbation theory, and
non-linear perturbation theory, respectively) in the extended Press-Schechter
formalism. Our code is publicly available at
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neutral hydrogen atoms. Yet, although hydrogen atoms belong to the sub-class of
baryonic matter, it is customary to simplify their treatment and analyze the
21-cm signal as if all the matter in the Universe was in the form of
collisionless cold dark matter (CDM). This is usually done by evolving the
density field via a scale-independent growth factor (SIGF). In this work, we
separate the baryons from CDM and evolve the two species with a proper
scale-dependent growth factor (SDGF). By incorporating the SDGF in the
21cmFirstCLASS code, we demonstrate the effect that baryons and CDM have on the
21-cm signal at the linear dark ages epoch and the subsequent non-linear epochs
of cosmic dawn and reionization. Our analysis shows that the baryonic nature of
hydrogen cannot be ignored during the dark ages, and that non-linear effects in
density-field evolution must be accounted for after stars have formed.
Furthermore, we discuss how the 21-cm signal is modified at lower redshifts,
where ground-based 21-cm interferometers are mostly sensitive, due to the
choice of working with either the "linear" or "non-linear" matter over-density
(that is, the over-density as computed from linear perturbation theory, and
non-linear perturbation theory, respectively) in the extended Press-Schechter
formalism. Our code is publicly available at
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neutral hydrogen atoms. Yet, although hydrogen atoms belong to the sub-class of
baryonic matter, it is customary to simplify their treatment and analyze the
21-cm signal as if all the matter in the Universe was in the form of
collisionless cold dark matter (CDM). This is usually done by evolving the
density field via a scale-independent growth factor (SIGF). In this work, we
separate the baryons from CDM and evolve the two species with a proper
scale-dependent growth factor (SDGF). By incorporating the SDGF in the
21cmFirstCLASS code, we demonstrate the effect that baryons and CDM have on the
21-cm signal at the linear dark ages epoch and the subsequent non-linear epochs
of cosmic dawn and reionization. Our analysis shows that the baryonic nature of
hydrogen cannot be ignored during the dark ages, and that non-linear effects in
density-field evolution must be accounted for after stars have formed.
Furthermore, we discuss how the 21-cm signal is modified at lower redshifts,
where ground-based 21-cm interferometers are mostly sensitive, due to the
choice of working with either the "linear" or "non-linear" matter over-density
(that is, the over-density as computed from linear perturbation theory, and
non-linear perturbation theory, respectively) in the extended Press-Schechter
formalism. Our code is publicly available at
https://github.com/jordanflitter/21cmFirstCLASS.</abstract><doi>10.48550/arxiv.2411.00089</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Physics - Cosmology and Nongalactic Astrophysics |
| title | Does it matter? A more careful treatment of density fluctuations in 21-cm simulations |
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