Category Archives: starbirth

astronomy, astronomy news, starbirth, stardust, stars

Diamonds Loose in the Sky

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All that Glitters

When you look at the night sky, of course you see stars glittering up there. And, planets.  And, if you  have a telescope, you can make out the blurry wisps of nebulae and galaxies.  Nebulae are clouds of gas and dust that float in space. They can be starbirth regions, the outpouring of a star (or stars) dying, and a mixture of both.

As it turns out, when you look at the clouds of gas and dust (called circumstellar disks) surrounding some special types of stars, you are looking at something else that glitters: diamonds.  In these regions, there are countless numbers of these tiny sparklers (and I do mean tiny — most are not even the width of a human hair) swarming around in those disks. Yet around some stars, there are enough diamond specks that if you packed them all together, they’d have enough mass to make a tiny moonlet.

https://i0.wp.com/www.naoj.org/Pressrelease/2009/04/14/goto_illust_e.jpg?resize=395%2C296
Artist's conception of where diamonds are found in circumstellar disks with special conditions that lead to the formation of such diamonds. Courtesy Subaru Telescope, NAOJ. (Click to embiggen.)

How can diamonds form in space? It’s a detective story, really, and a group of scientists from Japan, Germany, and Denmark used Subaru telescope on Mauna Kea in Hawai’i, to study ayoung star called Elias 1 to solve the central riddle of that story: how can diamonds form in space?

When scientists look for diamonds in space, they are like detectives using fingerprints to trace a missing person or find the perpetrator of a crime. The fingerprints of diamond crystals take the form of  lines in the infrared wavelength of light, outside the range of visible light. The first such signature was discovered in 1983 in the circumstellar disk of Elias 1, a young star located in the direction of Taurus. It is is one of many Herbig Ae/Be (HAEBE) stars?young, very bright stars that are about 1.5-10 times as massive as our Sun.

The research team began with clues from previous laboratory research into how diamonds are formed (carbon materials are subjected to  great temperatures and pressures).  They coupled this with observations of stars that are surrounded by dust, and have partner stars that emit tremendous bursts of hard x-ray emissions.   X-rays are emitted under extremely energetic and hot conditions, so that supplies the necessary energy and pressure for a natural diamond factory in space.

The scientists knew from their research that diamonds are formed close to the stars where they exist. They aren’t floating in from random points in space.  Also, diamond stars must have special ingredients: that disk full of carbon material, a hot central star and a companion emitting hard x-rays. The star must be of intermediate mass that can warm up the disk to a medium temperature. Then, carbon onions can form, providing the cradle for diamond creation. The need for such special conditions would explain why we see so few stars with diamond signatures in their disks.

The findings of this research (more details here) will raise even more questions and speculation about the formation of these fascinating crystals. It’s possible that there are tons of diamonds that astronomers cannot yet see because their emissions are hidden from view by shells of material surrounding the stars where they exist.

astronomy, spitzer space telescope, starbirth, UKIRT

A Seething Hotbed of Star Birth

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Another Peek at the Orion Nebula

It’s getting to be the time of year when the Orion Nebula isn’t readily available in the night sky because — well, it’s just not a sky sight for the next few months.  So, those of us who love to explore the nebula have to “make do” with the latest in professional studies of this busy, busy star birth region.

The Orion Molecular Cloud as seen by UKIRT and Spitzer Space Telescope. (Click to emiggen -- and you WANT to!)
The Orion Molecular Cloud as seen by UKIRT and Spitzer Space Telescope. (Click to embiggen -- and you WANT to!)

The kind folks at the United Kingdom Infrared Telescope (UKIRT), the IRAM Millimeter-wave Telescope in Spain,  and the orbiting Spitzer Space Telescope did a set of observations and combined them to create this stunning infrared image of the Orion Molecular Cloud. There’s a lot going on here —  star birth is NOT a serene event (just as human births aren’t exactly quiet, respectful events).

Let’s deconstruct this image. (You might want to right-click on it and open it in a new browser window to see all the details.)  First, the glowing green areas are clouds of gas and dust that are the seed material for stars. They’re usually made up of hydrogen gas and dust particles.  There are newborn stars in here — they glow in a sort of golden orange color and they’re heating up the cloud with their ultraviolet radiation. This causes the cloud to glow in a variety of wavelengths — some of them invisible to us — like infrared, which is what UKIRT, IRAM, and Spitzer are sensitive to.

So, it stands to reason that if you want to study the intricacies of star birth, you want to study the infrared light streaming from stellar nurseries.  It can cut right through most of the gas and dust in the region and give us a peek behind the clouds that often hide starbirth from us.

Newborn stars give off more than light and heat. They also emit jets during part of their infancy and childhood. Those jets shove their way out through the clouds and help sculpt the nebula.  In this image, the jets show up as tiny pink–purple arcs and dots.

A close-up of jets in the Orion Molecular Cloud (UKIRT WFCAM). (Click to embiggen.)
A close-up of jets in the Orion Molecular Cloud (UKIRT WFCAM). (Click to embiggen.)

To see the real action in this region, the astronomers took a close-up view of a jet streaming from a newborn star in one of the busier areas of star formation in this nebula.  The image was created from data acquired by the Wide Field Camera (WFCAM) at the United Kingdom Infrared Telescope.

The jet is in red, and you can see other objects — wisps, knots and filaments — that are also jets from other young stars. .

What I find cool about studying regions like the OMC is that at the same time they give us a look at star formation in the current age of the universe, they also give us a look back at the birth pangs of our own Sun and solar system some 4.5 billion years ago.  Some of the baby stars you see popping out here will someday BE like the Sun — and maybe even have their own planets.