Starship Asterisk*

Is the 1:99 ratio of visible to dark matter true in all known clusters with evidence of background galaxy lensing? If so, then the mass from the visible galaxies is insignificant. I am very much interested in looking at a modified version of these pictures with only the arced background galaxies and the foreground galaxies filtered out.

So far, gravitational lensing is the only way we "see/infer" location of large mass of dark matter.
Using what we could learn from these modified versions, survey the universe and search for faint spots of gravitational lensing with little or no visible galaxies in the foreground.
There are more dark matter than visible galaxy clusters, so I expect we will find plenty of "lensing" large clusters of mostly or only dark matter.

A police officer sees a drunken man intently searching the ground near a lamppost and asks him the goal of his quest. The inebriate replies that he is looking for his car keys, and the officer helps for a few minutes without success then he asks whether the man is certain that he dropped the keys near the lamppost.

“No,” is the reply, “I lost the keys somewhere across the street.” “Why look here?” asks the surprised and irritated officer. “The light is much better here,” the intoxicated man responds with aplomb.

K1NS wrote:

If the main mass of galaxies is rotating and moving, I would think that the blue arcs produced by lensing might actually change, in a time scale we might be able to observe. Are there multiple versions of this image, taken at different time, that look slightly different?

Light echoes, relativistic particles and microlensing can be observed to move within our galaxy
but observing any motion outside our galaxy is out of the question.

Chris Peterson wrote:

Ann wrote:Well, if we agree that the W475 filter has indeed detected all kinds of short-wave optical light, from deep violet up until the edge of green, and the Hubble image has shown all these short optical wavelengths to the same shade of blue, then I guess my original explanation still holds true.

Yes, but the actual filter it was collected in doesn't really matter. With redshifts on the order of 7, the only thing we're seeing in all the filter channels is photons originally emitted as UV- extreme UV, in fact. The W475 filter is collecting light emitted at around 50-70 nm, but even the longest wavelength light caught by the F850LP filter was emitted at just 125 nm - still extreme UV. So we're seeing these distant galaxies in an optical regime dominated by very high energy photons, produced not only by thermal processes (hot, young stars)^* but by synchrotron sources and other fairly exotic mechanisms.

^* for those with nanny filters in place, that's high temperature, newly formed stellar bodies.

Ann wrote:Well, if we agree that the W475 filter has indeed detected all kinds of short-wave optical light, from deep violet up until the edge of green, and the Hubble image has shown all these short optical wavelengths to the same shade of blue, then I guess my original explanation still holds true.

Ann wrote:Please explain this to me. I can understand that the "W" means "wide". But what about the "475"? Shouldn't that mean that the wide filter is centered on 475 nm?

In my opinion 475 nm is a blue color, not a green one. According to Joe Hanson, Ph.D. biologist and host/writer of PBS Digital Studios' It's Okay To Be Smart, 475 nm corresponds to the predominant wavelength of the blue sky.

Chris wrote:
(In this case, the blue display channel consists of data collected through a wideband green filter, 475W, meaning the light is probably on the whitish side visually).

ignacio_db wrote:Thanks for the response, very interesting. Let me see if I got this. What you are saying is that without the loss of energy that comes with electromagnetic emission, dark matter would not fall completely into a black hole, but stay orbiting it.

If so, then there should be a noteworthy accumulation of dark matter around black holes, wouldn't it?

Chris Peterson wrote:

ignacio_db wrote:Are black holes of dark matter possible in theory? If yes, Is there any observational evidence of their existence?

It isn't obvious what sort of matter we have once it is "inside" a black hole. Similarly, we don't really think of a black hole as being made out of any particular sort of matter. But black holes almost certainly can take in dark matter just like they do ordinary matter. The mechanism that allows matter to be captured by a black hole involves electromagnetic processes (an accretion disc behaves like a viscous fluid). Without that interaction, there isn't anything that allows dark matter orbits to decay significantly, so probably most of the matter that falls into black holes is ordinary. As far as mechanisms very early in the Universe that might have resulted in dark matter collapsing into black holes, I don't think there is much theory describing that.

ignacio_db wrote:
Are black holes of dark matter possible in theory?
If yes, Is there any observational evidence of their existence?

ignacio_db wrote:Are black holes of dark matter possible in theory? If yes, Is there any observational evidence of their existence?

K1NS wrote:

geckzilla wrote:

FloridaMike wrote:wait, wait, wait... I haven’t had a drink of the cool aid...

Isn’t "dark matter" just something we made up to explain something we don’t understand?

You don't usually make fringe statements like this, so I'm going to give you the benefit of the doubt, here... while it's true that it's not yet well understood, it's still the best explanation for the discrepancy between the mass of observable and the mass required for gravitational lensing such as Abell 1689.
https://en.wikipedia.org/wiki/Dark_matter

Try a taste of this. http://www.popsci.com/science/article/2 ... xplanation. You might find it more palatable than the Kool-Aid.

cindy4444 wrote:I thought dark matter was distinguished from gravitational matter. IN FACT, I thought that was what defined it-that it does not respond to gravity. If dark matter does respond and produce gravity, then what is the difference between dark matter and the regular kind we know and love? Is it just that we can not see the dark matter and SO do not know what it is. Hence my real question, may be what is it that makes matter "matter".? Obviously matter is defferent from energy but is there a scientific definition that covers regular and dark matter? Really would appreciate an answer from someone who knows the science.

geckzilla wrote:

FloridaMike wrote:wait, wait, wait... I haven’t had a drink of the cool aid...

Isn’t "dark matter" just something we made up to explain something we don’t understand?

You don't usually make fringe statements like this, so I'm going to give you the benefit of the doubt, here... while it's true that it's not yet well understood, it's still the best explanation for the discrepancy between the mass of observable and the mass required for gravitational lensing such as Abell 1689.
https://en.wikipedia.org/wiki/Dark_matter

FloridaMike wrote:wait, wait, wait... I haven’t had a drink of the cool aid...

Isn’t "dark matter" just something we made up to explain something we don’t understand?

The power of this enormous gravitational lens depends on its mass, but the visible matter, in the form of the cluster's yellowish galaxies, only accounts for about one percent of the mass needed to make the observed bluish arcing images of background galaxies. In fact, most of the gravitational mass required to warp space enough to explain this cosmic scale lensing is in the form of still mysterious dark matter.

neufer wrote:

K1NS wrote:
If the main mass of galaxies is rotating and moving, I would think that the blue arcs produced by lensing might actually change, in a time scale we might be able to observe. Are there multiple versions of this image, taken at different time, that look slightly different?

Light echoes, relativistic particles and microlensing can be observed to move within our galaxy
but observing any motion outside our galaxy is out of the question.

Ann wrote:

geckzilla wrote:
Lensed galaxies seem to emit shorter wavelength light than their foreground galaxies, though. That's why they always end up in the blue channel. That confuses me as well.

Lensing galaxies are typically massive elliptical galaxies made up almost exclusively of cool yellow stars. Far-away galaxies are typically small and full of star formation, which means that they shine very brightly in the ultraviolet channel. Their ultraviolet light has since become redshifted into the blue channel due to the expansion of the universe. Presumably, the red light that these background galaxies also emit have been redshifted out of the optical wavelengths altogether.