Our
Milky Way galaxy produces on average a few new stars every year across
the entire system. Massive young stars emit large amounts of
ultraviolet radiation which heats the local dust, and so the star
formation process results in infrared emission. The IRAS satellite,
launched by NASA in 1983 for a ten-month mission, discovered that some
galaxies in the universe are ultra-luminous, radiating a hundred or even
a thousand times as much light, mostly in the infrared, as does the
Milky Way.
Astronomers today attribute the source of that intense
luminosity to massive bursts of star formation, simply scaled-up
versions (called the Schmidt relation) of the processes in the Milky
Way. The colors and other morphological characteristics of
ultra-luminous galaxies are generally consistent with this
interpretation. If true, these galaxies are forming stars with
surprisingly high efficiencies and perhaps in unusual ways. Astronomers
refining their models are therefore investigating the extent to which
star formation rates can legitimately be derived from a simple scaling
relation, as well as the extent to which other processes like black hole
accretion at the nucleus might supplement the radiation from star
formation.
CfA astronomers Sarah Willis, Andres Guzman, Howard Smith, and Juan
Rafael Martinez-Galarza and their colleagues decided to investigate
these issues by examining the star formation activity in six regions of
current, massive star formation in our Milky Way. These molecular clouds
are thought to be small prototypes of the powerful star formation
regions active in luminous galaxies, but because the clouds are much
closer to us, it is possible to count directly the number of new stars
in them, rather than just infer their numbers from a luminosity as with
the Schmidt relation extrapolation.
Using infrared images from the
Spitzer Space Telescope, complemented by ground-based observations, the
team identified 2871 newly formed stars in these regions; they then
traced the stellar production rates in different zones across the
sources, using the visual extinction as a measure of the amount of dust
and gas present. Their results were roughly consistent with a
conventional Schmidt relation, but the astronomers found significant
deviations across the regions, with the most dramatic locations
producing stars a thousand times more efficiently than the least active
(but still star forming) regions. The scientists conclude that, at least
on the local scale, there is no universal relation between the density
of molecular gas and the star formation.
References:
"The Schmidt Law in Six Galactic Massive Star-forming Regions," S.
Willis, A. Guzman, M. Marengo, H. A. Smith, J. R. MartÃnez-Galarza, and
L. Allen, ApJ 809, 87, 2015.