Very low-luminosity galaxies in the early universe have observed sizes
similar to single star cluster complexes
R. Bouwens, P. van Dokkum, G. Illingworth, P. Oesch, M. Maseda, B. Ribeiro, and D. Lam. (2017)cite arxiv:1711.02090Comment: 23 pages, 14 figures, 4 tables, submitted to the Astrophysical Journal, Figures 9 and 10 show comparisons with the sizes and luminosities of local star cluster complexes and evolved objects, respectively, Figure 11 presents our constraints on the z~6 proto-globular cluster LF.
Abstract
We compare the sizes and luminosities of 307 faint z=6-8 sources revealed by
the Hubble Frontier Fields (HFF) program with sources in the nearby universe.
Making use of the latest lensing models and data from the first four HFF
clusters with an extensive suite of public lens models, we measure both the
sizes and luminosities for 153 z~6, 101 z~7, and 53 z~8 galaxies. The sizes
range over more than a decade from ~500 to <50 pc. Extremely small sizes are
inferred for many of our lowest luminosity sources, reaching individual sizes
as small as 10-30 pc (the smallest is 11(-6)(+28) pc). The uncertainty in these
measures ranges from 80 pc for the largest sources to typically about 20 pc for
the smallest. Such sizes are smaller than extrapolations of the size-luminosity
relation, and expectations for the completeness of our faint samples,
suggesting a likely break in the size-luminosity relation at ~-17 mag with size
proportional to L**(0.50(-0.11)(+0.10)). The sizes and luminosities of the
lowest-luminosity sources are similar to those of single star cluster complexes
like 30 Doradus in the lower-redshift universe and -- in a few cases -- super
star clusters. Remarkably, our identification of these compact, faint
star-forming sources in the z~6-8 universe also allow us to set upper limits on
the proto-globular cluster LF at z~6. Comparisons with recent models allow us
to rule out (with some caveats) some scenarios for proto-globular cluster
formation and set useful upper limits on other less extreme ones. Our results
suggest we may be very close to discovering a bona-fide population of forming
globular clusters at high redshift.
Description
[1711.02090] Very low-luminosity galaxies in the early universe have observed sizes similar to single star cluster complexes
cite arxiv:1711.02090Comment: 23 pages, 14 figures, 4 tables, submitted to the Astrophysical Journal, Figures 9 and 10 show comparisons with the sizes and luminosities of local star cluster complexes and evolved objects, respectively, Figure 11 presents our constraints on the z~6 proto-globular cluster LF
%0 Generic
%1 bouwens2017lowluminosity
%A Bouwens, R. J.
%A van Dokkum, P. G.
%A Illingworth, G. D.
%A Oesch, P. A.
%A Maseda, M.
%A Ribeiro, B.
%A Lam, D.
%D 2017
%K clusters galaxies high redshift size
%T Very low-luminosity galaxies in the early universe have observed sizes
similar to single star cluster complexes
%U http://arxiv.org/abs/1711.02090
%X We compare the sizes and luminosities of 307 faint z=6-8 sources revealed by
the Hubble Frontier Fields (HFF) program with sources in the nearby universe.
Making use of the latest lensing models and data from the first four HFF
clusters with an extensive suite of public lens models, we measure both the
sizes and luminosities for 153 z~6, 101 z~7, and 53 z~8 galaxies. The sizes
range over more than a decade from ~500 to <50 pc. Extremely small sizes are
inferred for many of our lowest luminosity sources, reaching individual sizes
as small as 10-30 pc (the smallest is 11(-6)(+28) pc). The uncertainty in these
measures ranges from 80 pc for the largest sources to typically about 20 pc for
the smallest. Such sizes are smaller than extrapolations of the size-luminosity
relation, and expectations for the completeness of our faint samples,
suggesting a likely break in the size-luminosity relation at ~-17 mag with size
proportional to L**(0.50(-0.11)(+0.10)). The sizes and luminosities of the
lowest-luminosity sources are similar to those of single star cluster complexes
like 30 Doradus in the lower-redshift universe and -- in a few cases -- super
star clusters. Remarkably, our identification of these compact, faint
star-forming sources in the z~6-8 universe also allow us to set upper limits on
the proto-globular cluster LF at z~6. Comparisons with recent models allow us
to rule out (with some caveats) some scenarios for proto-globular cluster
formation and set useful upper limits on other less extreme ones. Our results
suggest we may be very close to discovering a bona-fide population of forming
globular clusters at high redshift.
@misc{bouwens2017lowluminosity,
abstract = {We compare the sizes and luminosities of 307 faint z=6-8 sources revealed by
the Hubble Frontier Fields (HFF) program with sources in the nearby universe.
Making use of the latest lensing models and data from the first four HFF
clusters with an extensive suite of public lens models, we measure both the
sizes and luminosities for 153 z~6, 101 z~7, and 53 z~8 galaxies. The sizes
range over more than a decade from ~500 to <50 pc. Extremely small sizes are
inferred for many of our lowest luminosity sources, reaching individual sizes
as small as 10-30 pc (the smallest is 11(-6)(+28) pc). The uncertainty in these
measures ranges from 80 pc for the largest sources to typically about 20 pc for
the smallest. Such sizes are smaller than extrapolations of the size-luminosity
relation, and expectations for the completeness of our faint samples,
suggesting a likely break in the size-luminosity relation at ~-17 mag with size
proportional to L**(0.50(-0.11)(+0.10)). The sizes and luminosities of the
lowest-luminosity sources are similar to those of single star cluster complexes
like 30 Doradus in the lower-redshift universe and -- in a few cases -- super
star clusters. Remarkably, our identification of these compact, faint
star-forming sources in the z~6-8 universe also allow us to set upper limits on
the proto-globular cluster LF at z~6. Comparisons with recent models allow us
to rule out (with some caveats) some scenarios for proto-globular cluster
formation and set useful upper limits on other less extreme ones. Our results
suggest we may be very close to discovering a bona-fide population of forming
globular clusters at high redshift.},
added-at = {2017-11-08T10:57:25.000+0100},
author = {Bouwens, R. J. and van Dokkum, P. G. and Illingworth, G. D. and Oesch, P. A. and Maseda, M. and Ribeiro, B. and Lam, D.},
biburl = {https://www.bibsonomy.org/bibtex/2a7e4693e203eca42ebcf00f7e955a29d/miki},
description = {[1711.02090] Very low-luminosity galaxies in the early universe have observed sizes similar to single star cluster complexes},
interhash = {db00465beb5289841f6edf090e52d797},
intrahash = {a7e4693e203eca42ebcf00f7e955a29d},
keywords = {clusters galaxies high redshift size},
note = {cite arxiv:1711.02090Comment: 23 pages, 14 figures, 4 tables, submitted to the Astrophysical Journal, Figures 9 and 10 show comparisons with the sizes and luminosities of local star cluster complexes and evolved objects, respectively, Figure 11 presents our constraints on the z~6 proto-globular cluster LF},
timestamp = {2017-11-08T10:57:25.000+0100},
title = {Very low-luminosity galaxies in the early universe have observed sizes
similar to single star cluster complexes},
url = {http://arxiv.org/abs/1711.02090},
year = 2017
}