The ALPINE-ALMA [C II] survey. Dust attenuation curves at z=4.4-5.5
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The ALPINE-ALMA [C II] survey. Dust attenuation curves at z=4.4-5.5. / Boquien, Mederic; Buat, Veronique; Burgarella, Denis; Bardelli, Sandro; Bethermin, Matthieu; Faisst, Andreas; Ginolfi, Michele; Hathi, Nimish; Jones, Gareth; Koekemoer, Anton; Lemaux, Brian; Narayanan, Desika; Romano, Michael; Schaerer, Daniel; Vergani, Daniela; Zamorani, Giovanni; Zucca, Elena.
In: Astronomy & Astrophysics, Vol. 663, A50, 11.07.2022.Research output: Contribution to journal › Journal article › Research › peer-review
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TY - JOUR
T1 - The ALPINE-ALMA [C II] survey. Dust attenuation curves at z=4.4-5.5
AU - Boquien, Mederic
AU - Buat, Veronique
AU - Burgarella, Denis
AU - Bardelli, Sandro
AU - Bethermin, Matthieu
AU - Faisst, Andreas
AU - Ginolfi, Michele
AU - Hathi, Nimish
AU - Jones, Gareth
AU - Koekemoer, Anton
AU - Lemaux, Brian
AU - Narayanan, Desika
AU - Romano, Michael
AU - Schaerer, Daniel
AU - Vergani, Daniela
AU - Zamorani, Giovanni
AU - Zucca, Elena
PY - 2022/7/11
Y1 - 2022/7/11
N2 - Context. There is ample evidence that dust is already present in abundance at high redshift. However, given the faintness of distant galaxies in the optical and the near-infrared, the data are limited and the understanding of how the dust a ffects the emerging radiation of galaxies at very high redshift is still limited.Aims. Using the ALMA Large Program to INvestigate [C II] at Early times (ALPINE), our objective is to quantify the dust attenuation properties in galaxies at z = 4.4-5.5, particularly with regard to the shape of their attenuation curve.Methods. Using the CIGALE spectral energy distribution (SED) code, we modeled the stellar populations and their interactions with the dust to measure some of the physical properties of the ALPINE sample. We selected a subsample of 23 main-sequence galaxies requiring a detection in at least six bands in the rest-frame UV and optical, as well as in the dust continuum around 158 mu m or the [C II] fine-structure line. The inclusion of this line is important for improving the constraints on the physical properties, while achieving a reasonably low uncertainty on the slope of the attenuation curves.Results. We find that the attenuation curves span a broad range of properties - from curves that are much steeper than the SMC extinction curve to those that are shallower than the starburst attenuation curve. The shape of the attenuation curves strongly depends on the V-band attenuation. Galaxies with the lowest attenuation also present the steepest curves. The steepness of such curves probably results from the combination of the intrinsic physical properties of the dust, the relative distribution of stars and dust in the interstellar medium, and the di fferential reddening, with an important fraction of the dust concentrated in star-forming regions. The broad range of attenuation curves found at z similar to 5 shows that no single attenuation curve is appropriate for main-sequence galaxies. When SED modeling is not feasible, assuming a fixed curve can lead to large errors, for instance, in the interpretation and application of the IRX-beta diagram.Conclusions. Considerable caution should be exercised when correcting high redshift galaxies for the presence of dust using the UV slope beta as it can affect the estimation of both star formation rates and stellar mass even at low V-band attenuation due to the steepness of the attenuation curve. However, when SED modeling can be used, the impact of the choice of the attenuation curve on the star formation rate and the stellar mass is limited.
AB - Context. There is ample evidence that dust is already present in abundance at high redshift. However, given the faintness of distant galaxies in the optical and the near-infrared, the data are limited and the understanding of how the dust a ffects the emerging radiation of galaxies at very high redshift is still limited.Aims. Using the ALMA Large Program to INvestigate [C II] at Early times (ALPINE), our objective is to quantify the dust attenuation properties in galaxies at z = 4.4-5.5, particularly with regard to the shape of their attenuation curve.Methods. Using the CIGALE spectral energy distribution (SED) code, we modeled the stellar populations and their interactions with the dust to measure some of the physical properties of the ALPINE sample. We selected a subsample of 23 main-sequence galaxies requiring a detection in at least six bands in the rest-frame UV and optical, as well as in the dust continuum around 158 mu m or the [C II] fine-structure line. The inclusion of this line is important for improving the constraints on the physical properties, while achieving a reasonably low uncertainty on the slope of the attenuation curves.Results. We find that the attenuation curves span a broad range of properties - from curves that are much steeper than the SMC extinction curve to those that are shallower than the starburst attenuation curve. The shape of the attenuation curves strongly depends on the V-band attenuation. Galaxies with the lowest attenuation also present the steepest curves. The steepness of such curves probably results from the combination of the intrinsic physical properties of the dust, the relative distribution of stars and dust in the interstellar medium, and the di fferential reddening, with an important fraction of the dust concentrated in star-forming regions. The broad range of attenuation curves found at z similar to 5 shows that no single attenuation curve is appropriate for main-sequence galaxies. When SED modeling is not feasible, assuming a fixed curve can lead to large errors, for instance, in the interpretation and application of the IRX-beta diagram.Conclusions. Considerable caution should be exercised when correcting high redshift galaxies for the presence of dust using the UV slope beta as it can affect the estimation of both star formation rates and stellar mass even at low V-band attenuation due to the steepness of the attenuation curve. However, when SED modeling can be used, the impact of the choice of the attenuation curve on the star formation rate and the stellar mass is limited.
KW - galaxies: high-redshift
KW - STAR-FORMING GALAXIES
KW - LYMAN-BREAK GALAXIES
KW - IRX-BETA RELATION
KW - HIGH-REDSHIFT
KW - FAR-ULTRAVIOLET
KW - MAIN-SEQUENCE
KW - LEGACY SURVEY
KW - MILKY-WAY
KW - H-ALPHA
KW - TO 3
U2 - 10.1051/0004-6361/202142537
DO - 10.1051/0004-6361/202142537
M3 - Journal article
VL - 663
JO - Astronomy & Astrophysics
JF - Astronomy & Astrophysics
SN - 0004-6361
M1 - A50
ER -
ID: 315399507