Resolving the H I in damped Lyman α systems that power star formation.
Rongmon BordoloiJohn M O'MearaKeren SharonJane R RigbyJeff CookeAhmed ShabanMateusz MatuszewskiLuca RizziGreg DoppmannD Christopher MartinAnna M MoorePatrick MorrisseyJames D NeillPublished in: Nature (2022)
Reservoirs of dense atomic gas (primarily hydrogen) contain approximately 90 per cent of the neutral gas at a redshift of 3, and contribute to between 2 and 3 per cent of the total baryons in the Universe 1-4 . These 'damped Lyman α systems'-so called because they absorb Lyman α photons within and from background sources-have been studied for decades, but only through absorption lines present in the spectra of background quasars and γ-ray bursts 5-10 . Such pencil beams do not constrain the physical extent of the systems. Here we report integral-field spectroscopy of a bright, gravitationally lensed galaxy at a redshift of 2.7 with two foreground damped Lyman α systems. These systems are greater than 238 kiloparsecs squared in extent, with column densities of neutral hydrogen varying by more than an order of magnitude on scales of less than 3 kiloparsecs. The mean column densities are between 10 20.46 and 10 20.84 centimetres squared and the total masses are greater than 5.5 × 10 8 -1.4 × 10 9 times the mass of the Sun, showing that they contain the necessary fuel for the next generation of star formation, consistent with relatively massive, low-luminosity primeval galaxies at redshifts greater than 2.