Starship Asterisk*

JohnD wrote: ↑Wed Nov 27, 2019 9:21 am Is that another similar object visible thouth Hoag's ring gap? It looks more like a galaxy with several bright star-forming areas in the disc, not the uniform appearnce of Hoag.
John

https://en.wikipedia.org/wiki/Eye_of_Providence wrote:
<<The Eye of Providence (or the all-seeing eye of God) is a symbol showing an eye often surrounded by rays of light or a glory. Seventeenth-century depictions of the Eye of Providence sometimes show it surrounded by clouds or sunbursts.

It represents the eye of God watching over humanity.>>

Does it read lips?

BDanielMayfield wrote: ↑Wed Nov 27, 2019 7:17 am Hmm. As ring galaxies are quite rare, finding yet another distant ring galaxy perfectly framed inside another ring galaxy's gap is rather extraordinary. I wonder what could have caused ring galaxies to have a preference for forming in this particular direction?

Chris Peterson wrote: ↑Wed Nov 27, 2019 2:23 pm

BDanielMayfield wrote: ↑Wed Nov 27, 2019 7:17 am Hmm. As ring galaxies are quite rare, finding yet another distant ring galaxy perfectly framed inside another ring galaxy's gap is rather extraordinary. I wonder what could have caused ring galaxies to have a preference for forming in this particular direction?

While there is evidence of galaxy orientation alignment preferences over vast cosmological distances, taken in small numbers the orientations are still very close to random. It's unlikely that we're seeing anything more than coincidental alignment here, both in position and orientation.

BDanielMayfield wrote: ↑Wed Nov 27, 2019 4:46 pm

Chris Peterson wrote: ↑Wed Nov 27, 2019 2:23 pm

BDanielMayfield wrote: ↑Wed Nov 27, 2019 7:17 am Hmm. As ring galaxies are quite rare, finding yet another distant ring galaxy perfectly framed inside another ring galaxy's gap is rather extraordinary. I wonder what could have caused ring galaxies to have a preference for forming in this particular direction?

While there is evidence of galaxy orientation alignment preferences over vast cosmological distances, taken in small numbers the orientations are still very close to random. It's unlikely that we're seeing anything more than coincidental alignment here, both in position and orientation.

My science side is almost totally fine with that explanation, so yeah, this is probably just a random chance alignment. I just wonder, due to the rareness of such objects if there could be some natural process at work making this view less unlikely.

Chris Peterson wrote: ↑Wed Nov 27, 2019 4:53 pm

BDanielMayfield wrote: ↑Wed Nov 27, 2019 4:46 pm

Chris Peterson wrote: ↑Wed Nov 27, 2019 2:23 pm

While there is evidence of galaxy orientation alignment preferences over vast cosmological distances, taken in small numbers the orientations are still very close to random. It's unlikely that we're seeing anything more than coincidental alignment here, both in position and orientation.

My science side is almost totally fine with that explanation, so yeah, this is probably just a random chance alignment. I just wonder, due to the rareness of such objects if there could be some natural process at work making this view less unlikely.

Well, if there were some other [scientific] process at work, I think we'd expect to see other galaxies in that region of the sky (say, inside a 1° box or smaller) showing an orientation bias, but I don't think that's the case. And keep in mind that this is very observer location dependent. Any pair of galaxies whose planes are parallel to each other will present a similar view from the right locations in space.

BDanielMayfield wrote: ↑Wed Nov 27, 2019 5:55 pm

Chris Peterson wrote: ↑Wed Nov 27, 2019 4:53 pm

BDanielMayfield wrote: ↑Wed Nov 27, 2019 4:46 pm

My science side is almost totally fine with that explanation, so yeah, this is probably just a random chance alignment. I just wonder, due to the rareness of such objects if there could be some natural process at work making this view less unlikely.

Well, if there were some other [scientific] process at work, I think we'd expect to see other galaxies in that region of the sky (say, inside a 1° box or smaller) showing an orientation bias, but I don't think that's the case. And keep in mind that this is very observer location dependent. Any pair of galaxies whose planes are parallel to each other will present a similar view from the right locations in space.

Just for curiosity's sake, I wonder what the view looks like in the direct opposite direction, about 180 degrees away from Hoag's object? Almost certainly nothing like this view I'm almost, almost, nearly 100% certain, but it wouldn't hurt to look would it?

Ann wrote: ↑Wed Nov 27, 2019 3:58 pm

Lenticular ring galaxy, the Cartwheel galaxy. ESA/Hubble & NASA

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Let's look at a simulation of the formation of a ring galaxy:
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Click to play embedded YouTube video.

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Let's look at some cool ring galaxies!

https://en.wikipedia.org/wiki/Cartwheel_Galaxy wrote:

The Cartwheel galaxy in different light spectra (X-ray, ultraviolet, visible, and infrared). The image combines data from four different space-based observatories: the Chandra X-ray Observatory (purple), the Galaxy Evolution Explorer (ultraviolet/blue), the Hubble Space Telescope (visible/green), and the Spitzer Space Telescope (infrared/red). Image is 160 arcsec across. RA 00h 37m 41.10s Dec −33° 42′ 58.80″ in Sculptor. Credit: NASA/JPL/Caltech/P.Appleton et al. X-ray: NASA/CXC/A.Wolter & G.Trinchieri et al.

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<<The Cartwheel Galaxy (also known as ESO 350-40 or PGC 2248) is a lenticular galaxy and ring galaxy about 500 million light-years away in the constellation Sculptor. It is an estimated 150,000 light-years diameter, and has a mass of about 2.9–4.8 × 10⁹ solar masses; its outer ring has a circular velocity of 217 km/s. The Cartwheel galaxy shows non-thermal radio and optical spokes, but they are not the same spokes.

The galaxy was once a normal spiral galaxy before it apparently underwent a head-on collision with a smaller companion approximately 200 million years ago (i.e., 200 million years prior to the image). When the nearby galaxy passed through the Cartwheel Galaxy, the force of the collision caused a powerful shock wave through the galaxy, like a rock being tossed into a sandbed. Moving at high speed, the shock wave swept up gas and dust, creating a starburst around the galaxy's center portion that were unscathed. This explains the bluish ring around the center, brighter portion. It can be seen that the galaxy is beginning to retake the form of a normal spiral galaxy, with arms spreading out from a central core.

The unusual shape of the Cartwheel Galaxy may be due to a collision with a smaller galaxy such as those in the lower left of the image. The most recent star burst (star formation due to compression waves) has lit up the Cartwheel rim, which has a diameter larger than the Milky Way. Star formation via starburst galaxies, such as the Cartwheel Galaxy, results in the formation of large and extremely luminous stars. When massive stars explode as supernovas, they leave behind neutron stars and black holes. Some of these neutron stars and black holes have nearby companion stars, and become powerful sources of X-rays as they pull matter off their companions (also known as ultra and hyperluminous X-ray sources).[10] The brightest X-ray sources are likely black holes with companion stars, and appear as the white dots that lie along the rim of the X-ray image. The Cartwheel contains an exceptionally large number of these black hole binary X-ray sources, because many massive stars formed in the ring.>>

astroarchitect1 wrote: ↑Wed Nov 27, 2019 9:32 pm Just wondering... being that it's 600 million miles away, how do they know that the older, redder cluster of stars in what looks like the middle of the ring is actually in the middle of the ring and not simply aligned with our point of view and at a different distance? It's not like we can look at it from another place in the universe and see no parallax shift...

sillyworm 2 wrote: ↑Thu Nov 28, 2019 1:47 pm I'm leaning toward the theory that there were once bars and they have dissipated.

MottyGlix wrote: ↑Wed Nov 27, 2019 10:38 am In one of her videos, Dr Rebecca Smethurst discusses mechanisms for how Hoag's Object may have formed. I am especially impressed by the work of Elena Yannikova quoted there. That speaks of a gravitational effect that, over time, would have moved all the stars or star-forming gas in a certain range of radii from the center either hubward or rimward within the Object. I recall viewing this in this YouTube video

Click to play embedded YouTube video.

See, particularly, 11:33 to 13:55.

neufer wrote: ↑Wed Nov 27, 2019 6:29 pm

The extended (Chandra) X-ray emission (shown below) from the Cartwheel galaxy
to its small spiral galactic neighbor sure suggests a head-on collision.

Note that the small spiral galactic neighbor looks like it might also be reverberating as a small ring-galaxy.

So is the small ring galaxy in the Hoag's Object APOD not a "coincidental distant object"
but rather the hit-and-run perpetrator/penetrator.

edgardine wrote: ↑Thu Nov 28, 2019 8:28 pm

neufer wrote: ↑Wed Nov 27, 2019 6:29 pm

The extended (Chandra) X-ray emission (shown below) from the Cartwheel galaxy
to its small spiral galactic neighbor sure suggests a head-on collision.

Note that the small spiral galactic neighbor looks like it might also be reverberating as a small ring-galaxy.

So is the small ring galaxy in the Hoag's Object APOD not a "coincidental distant object"
but rather the hit-and-run perpetrator/penetrator.

Thank you Ann and Neufer for these suggestions.

Do we know the Redshift of the small ring galaxy in the Hoag's Object APOD ?

Chris Peterson wrote: ↑Wed Nov 27, 2019 10:26 pm
The core and the ring [of Hoag's Object] have exactly the same redshift,
z = 0.04244, which places them at the same distance from us.

neufer wrote: ↑Fri Nov 29, 2019 3:27 pm

edgardine wrote: ↑Thu Nov 28, 2019 8:28 pm

neufer wrote: ↑Wed Nov 27, 2019 6:29 pm

The extended (Chandra) X-ray emission (shown below) from the Cartwheel galaxy
to its small spiral galactic neighbor sure suggests a head-on collision.

Note that the small spiral galactic neighbor looks like it might also be reverberating as a small ring-galaxy.

So is the small ring galaxy in the Hoag's Object APOD not a "coincidental distant object"
but rather the hit-and-run perpetrator/penetrator.

Thank you Ann and Neufer for these suggestions.

Do we know the Redshift of the small ring galaxy in the Hoag's Object APOD ?

I'd sorta like to know that myself, edgardine.
..................................................................
From its size alone one might assume it is a "Hoag's Object" roughly ten times more distant: z ~ 0.4244

However, for it to be as red as it is entirely from cosmological redshift it would have to be z ~ 4.244

Coincidence or not, it is probably red primarily due to (supernova) dust generated by the collision itself.

Chris Peterson wrote: ↑Wed Nov 27, 2019 10:26 pm
The core and the ring [of Hoag's Object] have exactly the same redshift,
z = 0.04244, which places them at the same distance from us.

neufer wrote: ↑Fri Nov 29, 2019 3:27 pm
From its size alone one might assume it is a "Hoag's Object" roughly ten times more distant: z ~ 0.4244

However, for it to be as red as it is entirely from cosmological redshift it would have to be z ~ 4.244

Coincidence or not, it is probably red primarily due to (supernova) dust generated by the collision itself.

Chris Peterson wrote: ↑Wed Nov 27, 2019 10:26 pm
The core and the ring [of Hoag's Object] have exactly the same redshift,
z = 0.04244, which places them at the same distance from us.

Ann wrote: ↑Fri Nov 29, 2019 4:34 pm
So according to my expertise - I mean, my amateur opinion - the small red galaxy inside Hoag's Object is too small and red to be easily thought of as equidistant with Hoag's Object. Applying the theorem of Occam's Razor, I must instead conclude that the small red ring galaxy seen inside Hoag's Object appears small and red to us because it is much more distant than Hoag's Object itself.

However, my main concern over the idea that Hoag's Object and the small red ring galaxy seen inside are related is that both these ring galaxies are so perfectly shaped and undisturbed. No major collision must have perturbed their shapes for several Myr and possibly Gyr. Clears throat:

So my carefully considered conclusion is that these two galaxies are unrelated.

edgardine wrote: ↑Thu Nov 28, 2019 8:28 pm Do we know the Redshift of the small ring galaxy in the Hoag's Object APOD ?