Extreme Cosmic-Ray-Dominated-Regions: a new paradigm for high star formation density events in the Universe

Abstract

We examine in detail the recent proposal that extreme Cosmic-Ray-Dominated-Regions (CRDRs) characterize the ISM of galaxies during events of high-density star formation, fundamentally altering its initial conditions (Papadopoulos 2010). Solving the coupled chemical and thermal state equations for dense UV-shielded gas reveals that the large cosmic ray energy densities in such systems (UCR (few)x(103-104) UCR,Gal) will indeed raise the minimum temperature of this phase (where the initial conditions of star formation are set) from ~10K (as in the Milky Way) to (50-100)K. Moreover in such extreme CRDRs the gas temperature remains fully decoupled from that of the dust, with Tkin >> Tdust, even at high densities (n(H2)~105--106 cm-3), quite unlike CRDRs in the Milky Way where Tk Tdust when n(H2) >= 105 cm-3. These dramatically different star formation initial conditions will: a) boost the Jeans mass of UV-shielded gas regions by factors of ~10--100 with respect to those in quiescent or less extreme star forming systems, and b) "erase" the so-called inflection point of the effective equation of state (EOS) of molecular gas. Both these effects occur across the entire density range of typical molecular clouds, and may represent a new paradigm for all high-density star formation in the Universe, with cosmic rays as the key driving mechanism, operating efficiently even in the high dust extinction environments of extreme starbursts...