Starship Asterisk*

Chris Peterson wrote:

geckzilla wrote:I think maybe if when processing a galaxy cluster you could balance the colors for the lensed z-depth only and they would look more normal. I probably need to try this myself at some point. In fact, I will make it a point to look at the CLASH data and pick one to do soon.

Try it with this one. Map the 1050 filter to blue, the 1100 filter to green, and the 1250, 1400, and 1600 filters to red. That will be quite close to the emitted ranges for z=1.14. Then you'll just have to play around with color balance.

Chris Peterson wrote: No, gravitational lenses are nothing like our optical lenses. An optical lens has no power through its optical center, and increases in power as you move towards its edge. A gravitational lens has its maximum power in the center, and the power drops off with radial distance. If you were to make an optical equivalent of a gravitational lens, it would look something like the base of a wine glass, with the maximum curvature in the center and the minimum at the edges (and a singularity at the very center).

Gravitational lenses can't bring a distant object to focus; optically, they have no focal plane.

JuanAustin wrote:I've noticed thru the years of being an avid fan of APOD that photos that appear in their original format and sources are often opposite when they appear in APOD. I guess it doesn't matter in the grander scheme of life, but it's kinda annoying and i have to wonder why go thru the trouble of flipping and reorientating the originals? Not a big deal, just saying. thanks

MarkBour wrote:I'm thinking that when we make our own lenses, we make them in a shape that is convenient, to produce good optical results. However, these natural gravitational lenses are not shaped for our purposes. So, I'm wondering if that produces the kind of "optics" you are reporting. Are most gravitational lenses of a similar "shape", perhaps like looking at something through a spherical crystal ?

geckzilla wrote:I think maybe if when processing a galaxy cluster you could balance the colors for the lensed z-depth only and they would look more normal. I probably need to try this myself at some point. In fact, I will make it a point to look at the CLASH data and pick one to do soon.

Chris Peterson wrote:

Ann wrote:Judging from how I read the caption, the host galaxy can actually be seen in this picture, and it appears to be much less red (or magenta) than the supernova. The best explanation I can think of is that the supernova created an incredible amount of either infrared or redshifted visible light, but not very much UV light. The galaxy, on the other hand, emits a lot of UV light, which is seen as blue, yellow and orange light in today's APOD.

Here's a careful enlargement from the color managed original:

tiberius.jpg

The supernova itself shows 46% of its total energy emitted from 491-748 nm, 25% of its total energy emitted from 362-397 nm, and 29% of its total energy emitted from 203-292 nm. That makes the UV component a little high, perhaps, but this seems largely consistent with most supernovas.

The galaxy itself is a little harder to figure. Most of it is highly red biased, which is absolutely normal, meaning that the emitted light was substantially white (as is the case with virtually all galaxies). The blue edge, however, has most of its energy emitted in UV. Perhaps this galaxy is actually a pair in collision, or something else is going on producing a front of intense star formation. Even so, I'd expect more intensity in the visible than the IR, so something odd is happening there.

MarkBour wrote:

geckzilla wrote:It's something about the way they get lensed. There are always often oddly red cores with oddly blue arms for lensed galaxies. . . .

I'm thinking that when we make our own lenses, we make them in a shape that is convenient, to produce good optical results. However, these natural gravitational lenses are not shaped for our purposes. So, I'm wondering if that produces the kind of "optics" you are reporting. Are most gravitational lenses of a similar "shape", perhaps like looking at something through a spherical crystal ?

geckzilla wrote:It's something about the way they get lensed. There are always often oddly red cores with oddly blue arms for lensed galaxies. . . .

southern cross wrote:I find this such a remarkable image. The supernova itself is amazing to see, but aside from this, the way the light from the background galaxy/galaxies is smeared around the big foreground galaxy in concentric rings - wow! I wonder if Abell saw this in his original survey? And this leads to the next question that springs into my mind... when was the gravitational lensing effect first noticed?

ta152h0 wrote:as I look out my kitchen window at night ( facing south ) I am in awe of astronomers actually finding these things

Ann wrote:Judging from how I read the caption, the host galaxy can actually be seen in this picture, and it appears to be much less red (or magenta) than the supernova. The best explanation I can think of is that the supernova created an incredible amount of either infrared or redshifted visible light, but not very much UV light. The galaxy, on the other hand, emits a lot of UV light, which is seen as blue, yellow and orange light in today's APOD.

BDanielMayfield wrote:

Nitpicker wrote:The supernova is a lot further away than the cluster. That's the point, I think.

You're right. Is the SN's distance known then, I wonder?

Nitpicker wrote:The supernova is a lot further away than the cluster. That's the point, I think.

Ann wrote:I find it remarkable that the supernova is so very red, and much redder than its apparent host galaxy.

Edit: But I should add that from the inset detail images it certainly looks like it is. I should have just deleted this post. Never mind. Please forget I wrote this dumb question.

Nitpicker wrote:The supernova is a lot further away than the cluster. That's the point, I think.