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The Astronomy Fire Hose: Distant Galaxy Edition

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Peering Into the Gravitational House of Mirrors

What is it about galaxies that SO evoke our sense of space and distance?  Is it because they’re so big and magnificent? That they stretch across immense regions of space? The idea that these cosmic cities are thronged with stars? If you look at an image of a galaxy like the Milky Way, you see stars and regions where stars are born and die, and you see (if it has one) the central core with a black hole at its heart.

But, how did galaxies get started?  How were they born?  And what is their lifestyle like?  These are questions that astronomers are still working to answer. Understanding the origin and evolution of galaxies benefits from looking at galaxies in all stages of their lives.  And, so, astronomers look through billions of years of cosmic history to study some of the earliest galaxies.

This illustrates how gravitational lensing by foreground galaxies will influence the appearance of far more distant background galaxies. This means that as many as 20 percent of the most distant galaxies currently detected will appear brighter because their light is being amplified by the effects of foreground intense gravitational fields. The plane at far left contains background high-redshift galaxies. The middle plane contains foreground galaxies; their gravity amplifies the brightness of the background galaxies. The right plane shows how the field would look from Earth with the effects of gravitational lensing added. Distant galaxies that might otherwise be invisible appear due to lensing effects.

There’s a little bit of a problem looking back that far. We have to peer through what amounts to a cosmic “house of mirrors” to see the youngest galactic objects in the universe. Everything we see in this house of mirrors is distorted by a phenomenon called gravitational lensing. This occurs when light from a distant object is distorted by a massive object that is in the foreground.

Astronomers have started to apply this concept in a new way to determine the number of very distant galaxies and to measure the amount of something called “dark matter” in the universe.

So, how does gravitational lensing work?

Albert Einstein showed that gravity will cause light to bend. The effect is normally extremely small, but when light passes close to a very massive object such as a massive galaxy, a galaxy cluster, or a supermassive black hole, the bending of the light rays becomes more easily noticeable.

When light from a very distant object passes a galaxy much closer to us, it can detour around the foreground object. Typically, the light bends around the object in one of two, or four different routes. This magnifies the light from the more distant galaxy directly behind it. What you get is a sort of “natural telescope”, called a gravitational lens. It provides a larger and brighter — though also distorted — view of the distant galaxy.

A very massive object — or collection of objects — distorts the view of faint objects beyond it so much that the distant images are smeared into multiple arc-shaped images around the foreground object. This effect is a lot like looking through a glass soft drink bottle at a light on a balcony and noticing how it is distorted as it passes through the bottle.

This is a very cool idea and I remember back in graduate school first learning about lensing, and we all thought it was almost too weird. At that time, all we could really see were the brightest, most obvious lensed objects.  Now, we can see many of these distortions. And, as we move toward fainter and more distant objects, many of the more recently observed ones pushing the limits of the Hubble Space Telescope.  Even fainter ones will need something with more observing power.  If all goes well, those next generation objects to be observed will be more effectively handled by a new space telescope on the drawing boards — the James Webb Space Telescope (JWST).

First Light and Lensing

When you look back to when the universe was young, you are seeing extremely early objects (also known as “first light” objects) that are very far away. The older and farther away the object, the more foreground universe there is to look through, which means the greater the chance that there will be something heavy in the foreground to distort the background image.  Dr. Rogier Windhorst of Arizona State University, is doing research suggests that gravitational lensing is likely to dominate the observed properties of very early galaxies, those that are at most 650-480 million years old The halos of foreground galaxies when the universe was in its heydays of star formation (when it was about 3-6 billion years old) will gravitationally distort most of these very early objects.  This leads to an effect called “gravitational lensing bias” where we are seeing many things whose light is stretched by lensing.  He reported on that work today at the AAS meeting, by way of pointing out just how useful future telescopes, especially the JWST, will be in extending our view out to the early universe and dealing with this house of mirrors effect.

JWST will have to take this bias into account. Scientists like Windhorst and his colleagues will need to design new ways of handling the data from those observations to really help them understand just what it is those early, distant gravitationally lensed galaxies are doing… and how they evolve to become the galaxies we see today.

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More from the Astronomy Fire Hose

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Some Thoughts on a Galaxy of Possibilities

I am always amazed at the depth and breadth of discoveries in astronomy that get announced at these AAS meetings. I mean, we all KNOW it’s a big universe and there are always going to be amazing discoveries – but, what we don’t always know is just WHAT those finds will be.

Earlier today we heard from scientists using data from the Sloan Digital Sky Survey to create the largest multicolor image of the night sky. It’s essentially the Palomar Sky Survey of our time, but in digital format. You can browse through their work here, and eventually you’ll see much of their work in GalaxyZoo, World Wide Telescope, and GoogleSky.

As I sat there and listened to the scientists talk about their work, it struck me just how much astronomers learn each DAY and how LITTLE we see about it in the news media.  To be sure, there’s a LOT of news every day, and science has to struggle for attention among all the other events of our time.

An SDSS stellar map of the northern sky part of the sky as seen from Earth. It shows trails and streams of stars. These are from satellite galaxies of the Milky Way Galaxy that were torn apart as they strayed too far into our galaxy’s gravitational field of influence. The insets show new dwarf companions discovered by the SDSS (credit: V. Belokurov).

Did you know that astronomers are using the Sloan Survey using a technique called “spectroscopy” to look at the light from those stars and figure out their chemical compositions, the velocity (speed) they’re moving through space, and a host of other characteristics?  It’s true.  One of the coolest outcomes of such a study is that they can now tell which stars came from our own galaxy and which ones were or are parts of galaxies that are being sucked into the Milky Way galaxy.  Stars from galaxies being gobbled up have slight differences in their metallicity (the heavier elements they contain), as well as definite variations in their velocities and direction of travel.

These factors, in turn, give astronomers some important clues to how galaxies form – essentially, the Milky Way has gotten bigger by gobbling up stars from smaller galaxies that were once neighbors moving along the cosmic highway with it. Trace the characteristics of those stars spectroscopically and you learn more about the former neighbor satellites that are now mingling their stars with the Milky Way Galaxy.

Well… THAT was just one tiny part of what Sloan Digital Sky Survey scientists discussed this morning–just a small drip from the firehose of astronomy information flowing at this meeting.  There is literally a galaxy of science to be learned here.