The Deepest Photo Ever Taken 218
Astroturtle writes "Astronomers using the Hubble Space Telescope's powerful new Advanced Camera for Surveys (ACS) have taken the deepest visible-light image ever made of the sky. The 3.5-day (84-hour) exposure captures stars as faint as 31st magnitude, according to Tom M. Brown (Space Telescope Science Institute), who headed the eight-person team that took the picture."
Comment removed (Score:3, Funny)
article (Score:3, Informative)
The 3.5-day (84-hour) exposure captures stars as faint as 31st magnitude, according to Tom M. Brown (Space Telescope Science Institute), who headed the eight-person team that took the picture. This is a little more than 1 magnitude (2.5 times) fainter than the epochal Hubble Deep Fields, which were made with the Hubble's Wide Field and Planetary Camera 2. It is 6 billion times fainter than what can be seen with the naked eye.
Brown and his colleagues chose to point at a spot 1 southeast of M31, the Great Andromeda Galaxy, in order to get a census of faint stars populating M31's outer halo. The full ACS image is about 3.1 arcminutes square, the size of a sand grain held at arm's length against the sky. The ACS magnifies this small field into a vast panorama of some 300,000 stars and thousands of faint background galaxies. At M31's distance of 2.5 million light-years, the faintest of the stars are slightly less luminous than our Sun. A large fraction of the most distant galaxies appear patchy and irregular, testimony to the collisions and mergers in the early universe that built up the familiar galaxies we see closer around us today.
Most of the stars in the image indeed proved to be in M31's halo, judging from their colors and brightnesses. Moreover, they show a surprisingly wide range of estimated ages -- from 6 to 13 billion years, compared to 11 to 13 billion years for our Milky Way's halo stars. Perhaps M31 has captured and torn apart younger dwarf galaxies than our Milky Way has done. Or perhaps M31 underwent a massive, disruptive merger with a single large galaxy billions of years ago; in this scenario some of M31's younger disk stars could have been flung into its halo. Or maybe some combination of these events triggered waves of star formation in regions that ended up in M31's outer fringes.
The image was made in two colors: near-infrared and "visual" (a band spanning the part of the spectrum running from yellow through green). The renditions displayed here were crafted to resemble true-color views by interpolating from these two colors. These vignettes each show only about 1 percent of the ACS image. The full image is available from the Hubble Telescope's press site at various qualities and sizes (up to 128 megabytes), along with more highlights and a finder chart showing its relation to M31.
Plans are afoot for an even deeper "Ultra-Deep Field," which will use ACS for longer exposures in four colors and go slightly fainter still.
3.5 Day Exposure? (Score:5, Interesting)
Re:3.5 Day Exposure? (Score:5, Insightful)
Re:3.5 Day Exposure? (Score:2)
Re:3.5 Day Exposure? (Score:1)
and NASA couldn't afford 1600... (Score:5, Funny)
And, to think I used to complain about having to get the tripod out for exposures that were longer than 1/8th of a second! I'll never comlpain about slow film or lenses again!
Yeah, and you'd think NASA could afford 1600 ASA film for the price they paid for hubble...
I mean geez!
Re:3.5 Day Exposure? (Score:5, Informative)
As far as color and reciprocity, Hubble color shots are not always as the eye sees them. The famous "pillars of creation" shot for example, presented the light from oxygen ionization in one color, the light from sulfur ionization in another color, the light from hydogren ionization in another color.
Re:3.5 Day Exposure? (Score:5, Informative)
Re:3.5 Day Exposure? (Score:2)
>and figuratively) electronics.
Do you really mean `literally cool`?
The only thing worse than a grammar pedant is a grammar pedant who doesn't read the article he is criticizing. Since uneven heat flow would lead to spurious readings from a normal CCD; yes, I did 'really' mean 'literally cool'.
It would be interesting to know... (Score:4, Interesting)
Re:It would be interesting to know... (Score:3, Informative)
There are a few different ways of measuring magnitude (apparent, bolometric, etc). Bolometric is essentially the integral over all wavelengths. I'm guessing they didn't do a real bolometric measurement, but I could be wrong.
Anyway, the relationship between intensity (I) and apparent magnitude (m) is
Intensity is in units of power/area, such as W/m^2 or ergs/cm^2 (cg
Re:It would be interesting to know... (Score:1, Insightful)
MOD PARENT DOWN. (Score:2, Informative)
He doesn't deserve positive karma until he learns some respect. When he learns to treat people of all colors as he wishes to be treated himself, then perhaps he can contribute to the discussion in a worthwhile manner.
What goes around, comes around. Paranoid delusions about people of other races (sexes / political and religious beliefs) are so 1700's and have no place in
helps to be a professional astronomer... (Score:5, Interesting)
Let's suppose that the picture was taken in the "V" filter. I just happen to have the number of photons per second per meter squared that arrive from a star of 20th magnitude: 86.157. (taken from here [utoronto.ca]).
So the faintest stars in this picture are 31st magnitude? That's 11 mags fainter than 20, which by the handy old formula
mag1-mag2 = -2.5 * log(flux1/flux2)
which means that the 30th magnitude star puts out about 4x10^(-5) times as much flux.
Using the reference star's flux from above, this means that 0.0034299 photons per second per meter squared arrived at Hubble. The exposure was 84 hours, and the area of Hubble is (2.5m)^2*pi, so tada:
The total number of photons in the picture from the faintest star is: 20365.83
Still not too shabby. They probably could have found even fainter stuff.
Re:helps to be a professional troll... (Score:2)
Re:It would be interesting to know... (Score:2)
Re:It would be interesting to know... (Score:5, Informative)
Re:It would be interesting to know... (Score:1)
*takes lense off* (Score:1)
Details on the exposure techniques? (Score:5, Interesting)
Derek
Re:Details on the exposure techniques? (Score:3, Informative)
Re:Details on the exposure techniques? (Score:5, Informative)
When Hubble needs to move to a new target, engineers on Earth radio a signal to the HST flight computer. The flight computer then activates the Reaction Wheels.
Reaction wheels are heavy fly wheels that spin. As they spin, the momentum from their motion causes the telescope to move. There are four Reaction Wheels. By spinning each one at a certain speed and in a certain direction, engineers can point the telescop e anywhere they want.
Actually, rotates, not moves (Score:5, Informative)
As they spin, the momentum from their motion causes the telescope to move.
Well, it's techincally a litter different than that. The wheels don't actually cause hubble to translate within a plane. Instead they rotate hubble. By turning the spinning wheels, a torque is exerted on hubble, causing it to rotate.
neurostarRe:Details on the exposure techniques? (Score:5, Interesting)
Interesting. I was actually thinking more along the lines of automatic compensation, but I hadn't even thought about gyroscopes vs. impulse jets. I poked around a little on the hubble site for the instrumentation and flight computer and I found the handbooks for the instruments at this site [stsci.edu]. Appearently, the gyroscopes are used for coarse motion detection and the FGS uses constellational guidance. The manuals actually make a pretty interesting read.
On a side note, a constellational guidance is related to how head mount displays like UNC's HiBall [unc.edu] work.
Derek
Re:Details on the exposure techniques? (Score:2)
Another reason that gyros are used is much more practical: fuel storage limitations. For a satellite that is to be in orbit for years and will be constantly redirected, the fuel required for something like that would be many times the mass of the satellite, and thus impossible to put into orbit.
Re:Details on the exposure techniques? (Score:5, Informative)
(*) except for a small patch of sky called the CVZ: continuously visible zone
BTW, if you're keeping score at home, 30th magnitude is 1 trillion times fainter than the human eye can see!
[*shameless plug* Tom Brown is using my thesis code to analyze these data
Re:Details on the exposure techniques? (Score:2, Interesting)
Re:Details on the exposure techniques? (Score:4, Informative)
If only one star is available, guiding is still possible, but the field may slowly rotate, since one star only provides one of the two needed pointing constraints (of position and orientation).
A big project in preparation for Hubble was the creation of the Hubble Guide Star catalog, exactly for this purpose -- to make sure that given what people would want to observe, there would always be enough guide stars within an acceptable distance!
for more information, see here [stsci.edu] if you're interested! If you're ambitious, you can even read the instrument handbooks for yourself: here [stsci.edu]
Shameless karma whoring: (Score:5, Informative)
http://imgsrc.hubblesite.org/hu/db/2003/15/images
Re:Shameless karma whoring: (Score:2)
Man, that is high resolution!
Re:Shameless karma whoring: (Score:5, Funny)
Re:Shameless karma whoring: (Score:2)
Holy cow! (Score:5, Funny)
Unretouched excerpt from full-resolution image [evilpettingzoo.com].
Re:Holy cow! (Score:2)
Not sure what you mean. If you're asking, where in the original picture is this subimage, it's in the top slice, and almost all the way to the right, at least at my screen's resolution. At any resolution, it's bound to be pretty near the top right corner.
hubblesite.org news release (Score:5, Informative)
hubblesite.org (Score:5, Informative)
Hubblesite.org [hubblesite.org]
...hubblesite.org collapses into a singularity (Score:5, Funny)
For the love of all things scientific, have mercy on their 122MB TIFF image.
And to think that we've turned servers into slag by Slashdotting a 43kb page. [slashdot.org]
exposure time misleading (Score:5, Informative)
For those who are interested, the original hubble press release is located here [hubblesite.org].
The site includes the image in a variety of different formats, including a 123 MB tiff file.
Re:exposure time misleading (Score:2)
Philosophy: The Deepest Thought Ever Thunk (Score:2, Funny)
Streaks (Score:2, Insightful)
I'm just curious here, what are they? I thought maybe it could be a bit of space debris that whizzed in front of the camera, but with an exposure of 3.4 days, the streak would go from one side or another.
What moves that far in 3.4 days? A comet? A meteor? A star?
And that big bright cluster in the lower bottom, what's that? It looks pretty close galaxy-wise.
It's a neat pic for sure, a little blurry, which
Re:Streaks (Score:3, Interesting)
I'm just curious here, what are they? I thought maybe it could be a bit of space debris that whizzed in front of the camera, but with an exposure of 3.4 days, the streak would go from one side or another.
The streaks are probably something that moved, though some of them seem brighter in the center, which would indicate it was oscillating. I'm not exactly sure. Anything could move any distance in 3.4 days.
And t
Re:Globular Cluster (Score:1)
It does show impressively how good the resolution of the photograph is.
Re:Globular Cluster (Score:2)
Re:Streaks (Score:5, Informative)
The big bright cluster is actually a member of Andromedae (M31). Very impressive! The appearance of fuzziness is because the CCD oversamples the resolution of the telescope - which is necessary for good photometry - if you want it "sharp" then just bin the pixels by 2x2 or 3x3 or whatever looks best!
What's up with the points? (Score:4, Interesting)
The biggest example I see is about 3/4s of the way to the right and about 1/5 of the way down on the image, where there is a huge-looking star.
Why four points? Why do we see them even when the star itself is not in the picture (look on the top border for examples, like the one almost directly in the middle)? I guess I would expect that if the light source is too bright the spread would be in a circular formation and simply blur the star, not blur it in just those four directions so much stronger then the rest.
Is it just QM at play? If so, why it is almost always directly up, down, left, and right, instead of random and perhaps even changing over time directions (which probably would get right back to simply looking blurred)? Detector flaws?
It's due to the way telescopes are built. (Score:5, Informative)
(Astronomers understand the diffraction issues very well... it's usually not a problem; it just looks weird.)
- A friendly neighborhood astrophysicist
Re:What's up with the points? (Score:2, Informative)
Comment removed (Score:5, Informative)
Re:Not all scopes exhibit diffraction spikes. (Score:2)
I suspect that they leave them in because it looks dramatic and romantic for press releases. :)
Re: (Score:3, Informative)
Re: (Score:2)
Re:What's up with the points? (Score:2)
You know when you're watching a movie, if the lens points close to the sun, you see a sequence of little polygons move across the field? That's the image of the actual aperture being reflected off the many glass/glass and glass/air surfaces in the lens. (Modern lenses are complex, and are made of many "simple" lenses stacked together.)
Since the secondary mirror is in the "opening" of the telescope, it needs to be supported. The supports c
Re:What's up with the points? (Score:2, Informative)
No quantum mechanics, just plain ol' classical optics. Those are diffraction patterns. Crosses are the Fourier transform of a square, so I assume their aperature stop is a square.
-JS
Very impressed... (Score:3, Insightful)
Re:Very impressed... (Score:5, Interesting)
M 31 is 2.2 million light-years away. This is the galaxy that Hubble originally resolved into stars, thereby settling the Shapley-Curtis debate [nasa.gov] on the true scale of the Universe. However, the stars Hubble saw were the very brightest supergiants in M 31. In this HST image, we see stars 2 magnitudes fainter than the ancient main-sequence turn-off; i.e., stars which are intrinsically fainter than our Sun! This lets us learn a lot about the ages and chemical composition of M 31's halo stars, which turn out to be quite different from the stars in our halo (our halo is entirely composed of ancient, metal-poor stars; M 31's halo contains stars that are only 6 Gyr old, and much more metal-rich than our halo).
I heard Tom Brown give a talk on this work last week; very cool stuff.
Re:Then we're older, right? (Score:2)
Many galaxy formation models basically assume this fact: that the halo formed first and all at once, and then the gas that would become the disk collapsed down and started forming stars later, and at a more continuous pace. These models will now need to be reconsidered.
i still think this image is deeper... (Score:4, Funny)
This has to be the most expensive (Score:5, Funny)
The full size TIFF screensaver? (Score:2, Interesting)
I'd like to see it zoom in to the picture, while also changing x/y of the camera on a spline (etc). And each time choose a different starting point, and make it's speed adjustable.
All of those high-res pics are beautiful! maybe i'm 'a gonna dust off the
So awesome it's philosophical. (Score:5, Insightful)
Re:So awesome it's philosophical. (Score:2, Funny)
>reasses their place in the world
Almost, but not quite. I'm pretty damned cool.
Re:So awesome it's philosophical. (Score:2)
Bring out the telescope mirrors! (Score:2)
Man... (Score:1)
the deepest photo that will *ever* be taken (Score:4, Informative)
For an interesting article, see:
http://www.sciam.com/article.cfm?colID=1&articl
On parallel universes. Very interesting reading. If you're at a university, you will be able to browse the site's archives and access the nice PDF version of the article (which has the pictures supersized to full-page size).
Out of date knowledge (Score:2)
GP (Score:2)
Of course, my statement was oversimplistic. If we survie another 1 billion years, then the furthest object we'd be able to resolve would be 14.5-15 billion light years away.
Anyways, the article on parallel universes is very interesting. Somewhere out there, there's a universe where I'm dictator of the world!
Re:the deepest photo that will *ever* be taken (Score:5, Informative)
Here's your deepest image then:
http://map.gsfc.nasa.gov/m_ig/020598/02059
That's from the recent WMAP mission, which mapped the cosmic microwave background in exquisite detail, pinpointing the age of the Universe (and many other cosmological parameters) to high precision. You're looking at an all-sky image of the Universe as it looked when it was 100,000 years old, and became transparent for the first time. IOW, you are literally seeing the fires of creation.
Wow... I love science (Score:2)
Re:Wow... I love science (Score:2)
Re:Wow... I love science (Score:2)
Damn, (Score:5, Funny)
*This is a lame joke*
The sad thing is (Score:2)
Because of the nature of some posters/moderators on /., you felt that was a necessary fact to point out.
A Galaxy ... (Score:1)
Long, Long ago, far, far away
Rifed with Intergaltic Civil War.
Sorry, I mean Gentrification.
I guess 25 Million (?) light years just isnt enough
Re:A Galaxy ... (Score:3, Interesting)
Mirror of full JPG (Score:5, Informative)
http://wuarchive.wustl.edu/users/tom/mirrors/hu
is a mirror of the full JPEG - about 5M. Enjoy.
Big Picture... (Score:5, Interesting)
122.75 MB TIFF and More! (Score:3, Informative)
-Lucas
The imag is not blurred; thats whats interesting! (Score:3, Interesting)
This Nature [nature.com] article describes how....hmmm I had better quote:
"As a beam of starlight hops towards us through countless Planck times, its speed varies. This would smear the beam out so that different parts arrive at different times and distort our picture of where it came from. The longer the journey, the bigger the smear."
So that means that these deep Hubble photographs should all get more blurry the deeper you look and not razor sharp like we have come to love.
Its a fascinating problem!
Re:The imag is not blurred; thats whats interestin (Score:3, Informative)
[TMB]
Re:The imag is not blurred; thats whats interestin (Score:2)
"But wait!" you say. "Perhaps the graduate student in question would come up with a NEW and IMPROVED theory!" Right. In which case, her "theoretical prediction" would be EXACTLY what we're seeing, right? =)
Re:The imag is not blurred; thats whats interestin (Score:2)
*shrugs*
NOTE: I don't know what I'm talking about
Hey Autopr0n (Score:2)
Looks like your site has some opposition!!!!
Props to you, dude!!
How many stars are in the "visible" sky? (Score:3, Interesting)
a = angle subtended by capture (radians) = 2*pi*3.1/(360*60) = .000901
.0000008118
.0000000646
b = area of capture on a sphere of radius 1 =approx= a^2 =
c = fraction of entire sphere = b/(4*pi) =
d = number of visible stars in entire sky = 300000/c = 4,643,000,000,000
So that means almost 5 trillion stars are visible by Hubble in the entire sky. That's a lot of stars to catalog. (Assuming I didn't err like they did in the $97 trillion RIAA calculation... someone pls double check and flame me if appropriate.)
Re:How many stars are in the "visible" sky? (Score:3, Interesting)
Your mistake is the assumption that this image is representative of the entire sky's stellar density. HST was pointed near the Andromeda Galaxy for this image; almost all of the stars you are seeing are in the Andromeda Galaxy. Most points on the sky will have a much lower density of stars. See, for example, the Hubble Deep Field [hubblesite.org], which was purposely pointed at an "empty" region of sky, and which contains only a handful of stars.
Re:How many stars are in the "visible" sky? (Score:3, Interesting)
A photon and the naked eye (Score:2)
Something seems strange. I remember hearing that the human eye can discern a single photon, as from radioactive breakdown in a wristwatch face. I found something to back that up here [atmob.org] and here [prenhall.com] (actually apparently single photons are discarded as noise; 2 or three are better).
So by my c
Re:"Deep" Photo (Score:2, Redundant)
What I find fascinating is that they were able to keep the telescope still for that long. With a field of view that low, even microscopic rotations could ruin the shot.
Re:"Deep" Photo (Score:1)
I was trying to be humorous
Re:"Deep" Photo (Score:1)
Re:How? (Score:1)
Re:How? (Score:1, Insightful)
All in all... (Score:4, Interesting)
Re:All in all... (Score:3, Informative)
Not Several Millions, we're talking Billions...
According to http://hubble.nasa.gov/faq.html [nasa.gov] it cost $1.5 billion Plus another $230-250 million each year for maintenence. Estimated costs to fix the lens problem on the telescope were $20 million. Since the Hubble was launched in 1990 and is planned to operate until 2010, that's $230M per year for 20 years = $4.6 Billion + the $1.5 Billion initial cost. That's a total cost of operation equal to $6.1 Billion (low estimate that doesn't include the cost of
Re:All in all... (Score:2, Insightful)
Re:All in all... (Score:2)
but you're right, it *was* worth it!!!
Re:All in all... (Score:2)
2. Shuttle is extremely costly but the science done there is ho-hum and until recently a lot of it was not even done on level publishable in decent peer-revied journals.
Re:WOW (Score:1)