Small-scale Intensity Mapping: Extended Halos as a Probe of the Ionizing Escape Fraction and Faint Galaxy Populations during Reionization

We present a new method to quantify the value of the escape fraction of ionizing photons, and the existence of ultra-faint galaxies clustered around brighter objects during the epoch of cosmic reionization, using the diffuse Ly , continuum, and H emission observed around galaxies at . We model the s...

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Published inThe Astrophysical journal Vol. 846; no. 1; pp. 11 - 19
Main Authors Mas-Ribas, Lluís, Hennawi, Joseph F., Dijkstra, Mark, Davies, Frederick B., Stern, Jonathan, Rix, Hans-Walter
Format Journal Article
LanguageEnglish
Published Philadelphia The American Astronomical Society 01.09.2017
IOP Publishing
University of Chicago Press
Subjects
Astrophysics
ASTROPHYSICS, COSMOLOGY AND ASTRONOMY
BRIGHTNESS
COMPARATIVE EVALUATIONS
dark ages, reionization, first stars
Emission
FLUORESCENCE
Galactic halos
GALAXIES
galaxies: star formation
GALAXY CLUSTERS
Galaxy: halo
H alpha line
Halos
Ionization
James Webb Space Telescope
Mapping
Photons
RADIANT HEAT TRANSFER
Radiation
RADIATION SOURCES
radiative transfer
Satellite observation
SATELLITES
SPACE
Space telescopes
STAR EVOLUTION
Star formation
STARS
Stars & galaxies
Surface brightness
Systematics
TELESCOPES
Online AccessGet full text
ISSN0004-637X
1538-4357
DOI10.3847/1538-4357/aa8328

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Abstract We present a new method to quantify the value of the escape fraction of ionizing photons, and the existence of ultra-faint galaxies clustered around brighter objects during the epoch of cosmic reionization, using the diffuse Ly , continuum, and H emission observed around galaxies at . We model the surface brightness profiles of the diffuse halos, considering the fluorescent emission powered by ionizing photons escaping from the central galaxies, and the nebular emission from satellite star-forming sources, by extending the formalisms developed in Mas-Ribas & Dijkstra and Mas-Ribas et al. The comparison between our predicted profiles and Ly observations at z = 5.7 and z = 6.6 favors a low ionizing escape fraction, , for galaxies in the range . However, uncertainties and possible systematics in the observations do not allow for firm conclusions. We predict H and rest-frame visible continuum observations with the James Webb Space Telescope (JWST), and show that it will be able to detect extended (a few tens of kiloparsecs) fluorescent H emission powered by ionizing photons escaping from a bright, , galaxy. Such observations could differentiate fluorescent emission from nebular emission by satellite sources. We discuss how observations and stacking several objects may provide unique constraints on the escape fraction for faint galaxies and/or the abundance of ultra-faint radiation sources.
AbstractList We present a new method to quantify the value of the escape fraction of ionizing photons, and the existence of ultra-faint galaxies clustered around brighter objects during the epoch of cosmic reionization, using the diffuse Ly , continuum, and H emission observed around galaxies at . We model the surface brightness profiles of the diffuse halos, considering the fluorescent emission powered by ionizing photons escaping from the central galaxies, and the nebular emission from satellite star-forming sources, by extending the formalisms developed in Mas-Ribas & Dijkstra and Mas-Ribas et al. The comparison between our predicted profiles and Ly observations at z = 5.7 and z = 6.6 favors a low ionizing escape fraction, , for galaxies in the range . However, uncertainties and possible systematics in the observations do not allow for firm conclusions. We predict H and rest-frame visible continuum observations with the James Webb Space Telescope (JWST), and show that it will be able to detect extended (a few tens of kiloparsecs) fluorescent H emission powered by ionizing photons escaping from a bright, , galaxy. Such observations could differentiate fluorescent emission from nebular emission by satellite sources. We discuss how observations and stacking several objects may provide unique constraints on the escape fraction for faint galaxies and/or the abundance of ultra-faint radiation sources.
We present a new method to quantify the value of the escape fraction of ionizing photons, and the existence of ultra-faint galaxies clustered around brighter objects during the epoch of cosmic reionization, using the diffuse Lyα, continuum, and Hα emission observed around galaxies at \(z\sim 6\). We model the surface brightness profiles of the diffuse halos, considering the fluorescent emission powered by ionizing photons escaping from the central galaxies, and the nebular emission from satellite star-forming sources, by extending the formalisms developed in Mas-Ribas & Dijkstra and Mas-Ribas et al. The comparison between our predicted profiles and Lyα observations at z = 5.7 and z = 6.6 favors a low ionizing escape fraction, \({f}_{\mathrm{esc}}^{\mathrm{ion}}\sim 5 \% \), for galaxies in the range \(-19\gtrsim {M}_{\mathrm{UV}}\gtrsim -21.5\). However, uncertainties and possible systematics in the observations do not allow for firm conclusions. We predict Hα and rest-frame visible continuum observations with the James Webb Space Telescope (JWST), and show that it will be able to detect extended (a few tens of kiloparsecs) fluorescent Hα emission powered by ionizing photons escaping from a bright, \(L\gtrsim 5{L}^{* }\), galaxy. Such observations could differentiate fluorescent emission from nebular emission by satellite sources. We discuss how observations and stacking several objects may provide unique constraints on the escape fraction for faint galaxies and/or the abundance of ultra-faint radiation sources.
We present a new method to quantify the value of the escape fraction of ionizing photons, and the existence of ultra-faint galaxies clustered around brighter objects during the epoch of cosmic reionization, using the diffuse Ly α , continuum, and H α emission observed around galaxies at . We model the surface brightness profiles of the diffuse halos, considering the fluorescent emission powered by ionizing photons escaping from the central galaxies, and the nebular emission from satellite star-forming sources, by extending the formalisms developed in Mas-Ribas & Dijkstra and Mas-Ribas et al. The comparison between our predicted profiles and Ly α observations at z  = 5.7 and z  = 6.6 favors a low ionizing escape fraction, , for galaxies in the range . However, uncertainties and possible systematics in the observations do not allow for firm conclusions. We predict H α and rest-frame visible continuum observations with the James Webb Space Telescope ( JWST ), and show that it will be able to detect extended (a few tens of kiloparsecs) fluorescent H α emission powered by ionizing photons escaping from a bright, , galaxy. Such observations could differentiate fluorescent emission from nebular emission by satellite sources. We discuss how observations and stacking several objects may provide unique constraints on the escape fraction for faint galaxies and/or the abundance of ultra-faint radiation sources.
© 2017. The American Astronomical Society. All rights reserved.
We present a new method to quantify the value of the escape fraction of ionizing photons, and the existence of ultra-faint galaxies clustered around brighter objects during the epoch of cosmic reionization, using the diffuse Lyα, continuum, and Hα emission observed around galaxies at z∼6. We model the surface brightness profiles of the diffuse halos, considering the fluorescent emission powered by ionizing photons escaping from the central galaxies, and the nebular emission from satellite star-forming sources, by extending the formalisms developed in Mas-Ribas and Dijkstra and Mas-Ribas et al. The comparison between our predicted profiles and Lyα observations at z = 5.7 and z = 6.6 favors a low ionizing escape fraction, f{sub esc}{sup ion}∼5%, for galaxies in the range −19≳M{sub UV}≳−21.5. However, uncertainties and possible systematics in the observations do not allow for firm conclusions. We predict Hα and rest-frame visible continuum observations with the James Webb Space Telescope (JWST), and show that it will be able to detect extended (a few tens of kiloparsecs) fluorescent Hα emission powered by ionizing photons escaping from a bright, L≳5L{sup ∗}, galaxy. Such observations could differentiate fluorescent emission from nebular emission by satellite sources. We discuss how observations and stacking several objects may provide unique constraints on the escape fraction for faint galaxies and/or the abundance of ultra-faint radiation sources.
Author Hennawi, Joseph F.
Stern, Jonathan
Mas-Ribas, Lluís
Dijkstra, Mark
Davies, Frederick B.
Rix, Hans-Walter
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  givenname: Joseph F.
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  fullname: Dijkstra, Mark
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  surname: Rix
  fullname: Rix, Hans-Walter
  organization: Max-Planck-Institut für Astronomie, Königstuhl 17, D-69117 Heidelberg, Germany
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Snippet We present a new method to quantify the value of the escape fraction of ionizing photons, and the existence of ultra-faint galaxies clustered around brighter...
© 2017. The American Astronomical Society. All rights reserved.
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SubjectTerms Astrophysics
ASTROPHYSICS, COSMOLOGY AND ASTRONOMY
BRIGHTNESS
COMPARATIVE EVALUATIONS
dark ages, reionization, first stars
Emission
FLUORESCENCE
Galactic halos
GALAXIES
galaxies: star formation
GALAXY CLUSTERS
Galaxy: halo
H alpha line
Halos
Ionization
James Webb Space Telescope
Mapping
Photons
RADIANT HEAT TRANSFER
Radiation
RADIATION SOURCES
radiative transfer
Satellite observation
SATELLITES
SPACE
Space telescopes
STAR EVOLUTION
Star formation
STARS
Stars & galaxies
Surface brightness
Systematics
TELESCOPES
Title Small-scale Intensity Mapping: Extended Halos as a Probe of the Ionizing Escape Fraction and Faint Galaxy Populations during Reionization
URI https://iopscience.iop.org/article/10.3847/1538-4357/aa8328
https://www.proquest.com/docview/2365862573
http://hdl.handle.net/10852/60225
https://www.osti.gov/biblio/22875876
Volume 846
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