An Initial Mass Function for Individual Stars in Galactic Disks: I. Constraining the Shape of the IMF

Abstract

We derive a semi-empirical galactic initial mass function (IMF) from observational constraints. We assume that the star formation rate in a galaxy can be expressed as the product of the IMF, (m), which is a smooth function of mass m (in units of ), and a time- and space-dependent total rate of star formation per unit area of galactic disk. The mass dependence of the proposed IMF is determined by five parameters: the low-mass slope γ, the high-mass slope -, the characteristic mass mch (which is close to the mass m peak at which the IMF turns over), and the lower and upper limits on the mass, ml (taken to be 0.004) and mu (taken to be 120). The star formation rate in terms of number of stars per unit area of galactic disk per unit logarithmic mass interval, is proportional to m- \1-[-(m/mch)γ +]\, where N* is the number of stars, ml<m<mu is the range of stellar masses. The values of γ and are derived from two integral constraints: i) the ratio of the number density of stars in the range m=0.1-0.6 to that in the range m=0.6-0.8 as inferred from the mass distribution of field stars in the local neighborhood, and ii) the ratio of the number of stars in the range m=0.08 - 1 to the number of brown dwarfs in the range m=0.03-0.08 in young clusters. The IMF satisfying the above constraints is characterized by the parameters γ=0.51 and =0.35 (which corresponds to m peak=0.27). This IMF agrees quite well with the Chabrier (2005) IMF for the entire mass range over which we have compared with data, but predicts significantly more stars with masses < 0.03\, M; we also compare with other IMFs in current use.