Five-colour infrared image of a reservoir of cold gas in the constellation of the Southern Cross. The region is located about 60° from the Galactic Centre, thousands of light-years from Earth. The images cover an area of 2°x2° on the sky.
The images taken on 3 September reveal structure in cold material in our Galaxy, as we have never seen it before. Even before a detailed analysis, scientists have gleaned information on the quantity of the material, its mass, temperature, composition and whether it is collapsing to form new stars.
That a dark, cool area such as this would be bustling with activity, was unexpected. But the images reveal a surprising amount of turmoil: the interstellar material is condensing into continuous and interconnected filaments glowing from the light emitted by new-born stars at various stages of development. Ours is a tireless Galaxy constantly forging new generations of stars.
Stars form in cold, dense environments, and in these images it is easy to locate the star-forming filaments that would be very difficult to isolate in a single-wavelength image.
Traditionally, in a crowded region like this, situated in the plane of our Galaxy and containing many molecular clouds along the line of sight, astronomers have had a difficult time resolving details. But Herschel’s sophisticated infrared instruments made short work of the task, seeing through the dust that is opaque to visible light, and seeing the glow from the dust itself. These observations are not possible from ground.
The result is a view of an incredible network of filamentary structures, and features indicating a chain of near-simultaneous star-formation events, glittering like strings of pearls deep in our Galaxy.
The five original infrared wavelengths have been colour-coded to allow scientists to differentiate extremely cold material (red) from the surrounding warm stuff (blue).
The SPIRE and PACS images have been combined to a single composite; here blue denotes 70 micron and green 160 micron emission, while red is the combination of the emission from all three SPIRE bands at 250, 350 and 500 microns.