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Carbonaceous dust grains within galaxies seen in the first billion years of cosmic time

Authors :
Witstok, Joris
Shivaei, Irene
Smit, Renske
Maiolino, Roberto
Carniani, Stefano
Curtis-Lake, Emma
Ferruit, Pierre
Arribas, Santiago
Bunker, Andrew J.
Cameron, Alex J.
Charlot, Stephane
Chevallard, Jacopo
Curti, Mirko
de Graaff, Anna
D'Eugenio, Francesco
Giardino, Giovanna
Looser, Tobias J.
Rawle, Tim
del Pino, Bruno Rodríguez
Willott, Chris
Alberts, Stacey
Baker, William M.
Boyett, Kristan
Egami, Eiichi
Eisenstein, Daniel J.
Endsley, Ryan
Hainline, Kevin N.
Ji, Zhiyuan
Johnson, Benjamin D.
Kumari, Nimisha
Lyu, Jianwei
Nelson, Erica
Perna, Michele
Rieke, Marcia
Robertson, Brant E.
Sandles, Lester
Saxena, Aayush
Scholtz, Jan
Sun, Fengwu
Tacchella, Sandro
Williams, Christina C.
Willmer, Christopher N. A.
Publication Year :
2023
Publisher :
arXiv, 2023.

Abstract

Interstellar dust captures a significant fraction of elements heavier than helium in the solid state and is an indispensable component both in theory and observations of galaxy evolution. Dust emission is generally the primary coolant of the interstellar medium (ISM) and facilitates the gravitational collapse and fragmentation of gas clouds from which stars form, while altering the emission spectrum of galaxies from ultraviolet (UV) to far-infrared wavelengths through the reprocessing of starlight. However, the astrophysical origin of various types of dust grains remains an open question, especially in the early Universe. Here we report direct evidence for the presence of carbonaceous grains from the detection of the broad UV absorption feature around $2175 \, \mathring{\rm A}$ in deep near-infrared spectra of galaxies up to the first billion years of cosmic time, at a redshift ($z$) of $\sim 7$. This dust attenuation feature has previously only been observed spectroscopically in older, more evolved galaxies at redshifts of $z < 3$. The carbonaceous grains giving rise to this feature are often thought to be produced on timescales of hundreds of millions of years by asymptotic giant branch (AGB) stars. Our results suggest a more rapid production scenario, likely in supernova (SN) ejecta.<br />27 pages, 7 figures. Submitted

Details

Database :
OpenAIRE
Accession number :
edsair.doi.dedup.....b101c89acf60b20119743f2ff7ebcfd7
Full Text :
https://doi.org/10.48550/arxiv.2302.05468