Large metallicity variations in the Galactic interstellar medium

Annalisa Cia (), Edward B. Jenkins, Andrew J. Fox, Cédric Ledoux, Tanita Ramburuth-Hurt, Christina Konstantopoulou, Patrick Petitjean and Jens-Kristian Krogager
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Annalisa Cia: University of Geneva
Edward B. Jenkins: Princeton University Observatory
Andrew J. Fox: Space Telescope Science Institute
Cédric Ledoux: European Southern Observatory
Tanita Ramburuth-Hurt: University of Geneva
Christina Konstantopoulou: University of Geneva
Patrick Petitjean: Sorbonne Universités & CNRS
Jens-Kristian Krogager: University of Geneva

Nature, 2021, vol. 597, issue 7875, 206-208

Abstract: Abstract The interstellar medium (ISM) comprises gases at different temperatures and densities, including ionized, atomic and molecular species, and dust particles1. The neutral ISM is dominated by neutral hydrogen2 and has ionization fractions of up to eight per cent3. The concentration of chemical elements heavier than helium (metallicity) spans orders of magnitudes in Galactic stars4, because they formed at different times. However, the gas in the vicinity of the Sun is assumed to be well mixed and to have a solar metallicity in traditional chemical evolution models5. The ISM chemical abundances can be accurately measured with ultraviolet absorption-line spectroscopy. However, the effects of dust depletion6–9—which removes part of the metals from the observable gaseous phase and incorporates it into solid grains—have prevented, until recently, a deeper investigation of the ISM metallicity. Here we report the dust-corrected metallicity of the neutral ISM measured towards 25 stars in our Galaxy. We find large variations in metallicity over a factor of ten (with an average of 55 ± 7 per cent solar metallicity and a standard deviation of 0.28 dex), including many regions of low metallicity, down to about 17 per cent solar metallicity and possibly below. Pristine gas falling onto the Galactic disk in the form of high-velocity clouds can cause the observed chemical inhomogeneities on scales of tens of parsecs. Our results suggest that this low-metallicity accreting gas does not efficiently mix into the ISM, which may help us understand metallicity deviations in nearby coeval stars.

Date: 2021
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DOI: 10.1038/s41586-021-03780-0

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