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Abstract A sizable fraction of the heavy elements synthesized by stars in galaxies condenses into sub-micron-sized solid-state particles, known as dust grains¹, 2. Dust produces a wavelength-dependent attenuation, Aλ, of the galaxy emission, thereby significantly altering its observed properties³. Locally, Aλ is in general the sum of a power-law and a UV feature (’bump’) ⁴ produced by small, carbon-based grains⁵. However, scant information exists regarding its evolution across cosmic time. Here, leveraging data from 173 galaxies observed by the James Webb Space Telescope in the redshift range z = 2 − 12⁶, we report the most distant detection of the UV bump in a z ∼ 7. 55 galaxy (when the Universe was only ∼ 700 Myr old), and show for the first time that the power-law slope and the bump strength decrease towards high redshifts. We propose that the flat Aλ shape at early epochs is produced by large grains newly formed in supernova ejecta⁷, which act as the main dust factories at such early epochs. Importantly, these grains have undergone minimal reprocessing in the interstellar medium due to the limited available cosmic time⁸. This discovery opens new perspectives in the study of cosmic dust origin and evolution.
Markov et al. (Thu,) studied this question.
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