The galactic disk mass budget. I. Stellar mass function and density

In this paper, we use the general theory worked out within the past few years for the structure and the evolution of low-mass stars to derive the stellar mass function in the Galactic disk down to the vicinity of the hydrogen-burning limit from the observed nearby luminosity functions. The accuracy of the mass-magnitude relationships derived from the aforementioned theory is examined by comparison with recent, accurate observational relationships in the M-dwarf domain. The mass function is shown to flatten out below similar to1 M-circle dot but to keep rising down to the bottom of the main sequence. Combining the present determination below 1 M-circle dot and J. M. Scalo's mass function for larger masses, we show that the mass function is well described over the entire stellar mass range, from similar to 100 M-circle dot to similar to0.1 M-circle dot by three functional forms, namely, a two-segment power law, a lognormal form, or an exponential form, all normalized to the Hipparcos sample at 0.8 M-circle dot. Integration of this mass function yields a reasonably accurate census of the entire stellar population in the Galactic disk and its volume and surface mass density.