Abstract
Cosmic history has witnessed the lives and deaths of multiple generations of massive stars, all of them invigorating their host galaxies with ionizing photons, kinetic energy, fresh material, and stellar-mass black holes. Ubiquitous engines as they are, astrophysics needs a good understanding of their formation, evolution, properties and yields throughout the history of the Universe, and with decreasing metal content mimicking the environment at the earliest epochs. Ultimately, a physical model that could be extrapolated to zero metallicity would enable tackling long-standing questions such as “What did the first, very massive stars of the Universe look like?” or “What was their role in the re-ionization of the Universe?” Yet, most of our knowledge of metal-poor massive stars is drawn from one single point in metallicity. Massive stars in the Small Magellanic Cloud (SMC, sim 1/5Z⊙ ) currently serve as templates for low-metallicity objects in the early Universe, even though significant differences with respect to massive stars with poorer metal content have been reported. This White Paper summarizes the current knowledge on extremely (sub-SMC) metal poor massive stars, highlighting the most outstanding open questions and the need to supersede the SMC as standard. A new paradigm can be built from nearby extremely metal-poor galaxies that make a new metallicity ladder, but massive stars in these galaxies are out of reach to current observational facilities. Such a task would require an L-size mission, consisting of a 10m-class space telescope operating in the optical and the ultraviolet ranges. Alternatively, we propose that ESA unites efforts with NASA to make the LUVOIR mission concept a reality, thus continuing the successful partnership that made the Hubble Space Telescope one of the greatest observatories of all time.
Highlights
Scientific rationaleMassive stars are stellar-size objects of broad astrophysical impact. Born with M>8 M they live fast and die spectacularly, making an excellent source of fast chemical enrichment in their host galaxy
Experimental Astronomy (2021) 51:887–911 the successful partnership that made the Hubble Space Telescope one of the greatest observatories of all time
Our partial understanding of extremely metal-poor massive stars jeopardizes the interpretation of SNe and long-GRBs, star-forming galaxies throughout cosmic history, and the re-ionization epoch
Summary
Massive stars are stellar-size objects of broad astrophysical impact. Born with M>8 M they live fast and die spectacularly, making an excellent source of fast chemical enrichment in their host galaxy. Because the cosmic chemical complexity is ever-growing after the Big Bang, simulating these phenomena in past systems and interpreting the available observations demand robust models for the atmospheres, evolution, and feedback of massive stars at ever-decreasing metallicity. The massive stars of the Small Magellanic Cloud (SMC) constitute the current standard of the metal-poor regime, with a battery of observations from ground- and space-based telescopes providing empirical evidence and constraints to theory (e.g. 21, 36, 83, 94, 99, 106, 142). All this is integrated into population synthesis codes used to interpret observations of star-forming galaxies along cosmic history. New scenarios that we may expect from the theoretical predictions, how far we have reached with current observatories, and prospects for future missions in the planning
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