The VISTA telescope at Chile’s Paranal Observatory, which has been up and running since December 2009, has captured stunning new images of the Orion Nebula. By measuring infrared radiation emanating from the famous nebula, the telescope has finally seen into the heart of the vast stellar nursery.

This nebula, which is located below the “belt” of the constellation of Orion, can typically be seen from Earth with the naked eye. Large clouds of dust, however, have blocked optical wavelengths of light from reaching telescopes, preventing a clear view of the nebula’s center. By detecting the infrared radiation that penetrates dust clouds, astronomers are finally getting a look at the young stars shining in this previously hidden portion of the nebula.

These images are some of the first to be released from the new VISTA telescope; already they hint at the valuable new perspective astronomers are gaining by looking at the sky in near-infrared wavelengths of light.

To learn about other recent advances in astronomy, check out the Science Bulletins website.

The telescope technique of adaptive optics is rapidly advancing, allowing unprecedented ground-based views of distant galaxies, stars, and planets both inside and outside our Solar System. Adaptive optics reduces the greatest obstacle to a clear picture for telescopes viewing the sky from Earth: interference from our own planet’s atmosphere.

Astronomers with the European Southern Observatory recently used adaptive optics to spot details in the core of NGC 253, one of the brightest and dustiest spiral galaxies in the sky. The new image shows that the core is packed with massive nurseries of young stars. The observations also suggest that the supermassive black hole at this galaxy’s center is similar to the one at the center of the Milky Way. Learning more details about our galactic neighbors allows researchers to better understand how our own galaxy compares to the crowd.

To learn about other recent astronomical discoveries, visit the Science Bulletins website.

The speed of star formation from diffuse hydrogen gas has been a subject of strong controversy in the last decade. On one side, it is argued that magnetic fields act to support ionized interstellar gas against gravitational collapse. Then, almost every ion in the gas would need to find an electron to neutralize it before the gas could decouple from the magnetic field and collapse. This would suggest that it takes more than 10 million years to form a star. On the other side, it is argued that gas can slide along the magnetic field lines, allowing gas to accumulate and reach densities high enough for gravity to take hold and cause collapse, dragging the field lines with it. This suggests that a cloud will collapse into a star in only a few million years.

Young stars are deeply embedded within the collapsing clouds of gas and dust from which they form. While dust absorbs the visible light from those young stars, it emits strongly at mid-infrared wavelengths. By studying infrared images of galaxies, the star-forming regions are easily located within a galaxy's spiral arms.

In this study, the rotation of spiral arms through a galaxy is used to directly measure the time scale for star formation. The spiral arms rotate through the galaxy with a measurable speed. Therefore, a measurement of the distance between the peak of the gas emission (green contours) and the peak of the star formation emission (orange), will yield the time it took for the spiral arm to rotate through, and thus the time it took for the stars to form from the gas. The gas emission is observed using the hydrogen 21 centimeter radio emission.

Young stars are deeply embedded within the collapsing clouds of gas and dust from which they form. While dust absorbs the visible light from those young stars, it emits strongly at mid-infrared wavelengths. By studying infrared images of galaxies, the star-forming regions are easily located within a galaxy's spiral arms.

Measuring the relative positions of the star-forming emission versus the hydrogen gas emission in 14 galaxies resulted in time scales ranging from 1 to 4 million years, supporting the argument for fast collapse during star formation.