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Implications of a Temperature-dependent Initial Mass Function. II. An Updated View of the Star-forming Main Sequence

Charles L. Steinhardt, Albert Sneppen, Basel Mostafa, Hagan Hensley, Adam S. Jermyn, Adrian Lopez, John R. Weaver, Gabriel Brammer, Thomas H. Clark, I. Davidzon, Andrei Diaconu, Bahram Mobasher, Vadim Rusakov, Sune Toft

2022The Astrophysical Journal22 citationsDOIOpen Access PDF

Abstract

Abstract The stellar initial mass function (IMF) is predicted to depend upon the temperature of gas in star-forming molecular clouds. The introduction of an additional parameter, T IMF , into photometric template fitting, allows galaxies to be fit with a range of IMFs. Three surprising new features appear: (1) most star-forming galaxies are best fit with a bottom-lighter IMF than the Milky Way; (2) most star-forming galaxies at fixed redshift are fit with a very similar IMF; and (3) the most-massive star-forming galaxies at fixed redshift instead exhibit a less bottom-light IMF, similar to that measured in quiescent galaxies. Additionally, since stellar masses and star formation rates both depend on the IMF, these results slightly modify the resulting relationship, while yielding similar qualitative characteristics to previous studies.

Topics & Concepts

PhysicsStar (game theory)Sequence (biology)AstrophysicsMain sequenceFunction (biology)Effective temperatureInitial mass functionStellar evolutionStellar massAstronomyStarsStar formationEvolutionary biologyBiologyGeneticsAstrophysics and Star Formation StudiesScientific Research and DiscoveriesStellar, planetary, and galactic studies
Implications of a Temperature-dependent Initial Mass Function. II. An Updated View of the Star-forming Main Sequence | Litcius