I’m gonna be the grumpy old man here, but this is a marketing page. If there’s science going on here, it’s not even mentioned. Instead it’s all artist’s visualisations of infra-red data of an unusual galaxy. Is the galaxy of any scientific interest? I have no idea from the article whatsoever.
It's a pop sci article. It shows off advances in our imaging capabilities and hopefully inspires a little wonder about the universe. I believe the intended takeaway is something like "neat! We can see a lot of stuff going on in infrared that's hard to see in the visible spectrum". The rendering of other wavelengths as red, blue, and green pixels is a very standard scientific visualization method for multispectral imaging, and the article makes it clear what choices they make to do so.
It is interesting seeing past the central portion to see the complete rings on the back side. In the MIRI image, it looks like a special FX shot from some scifi where the explosion happens on a plane rather than a sphere.
i got nerd sniped and did the same thing myself. i could not find a way to blend the two images together that did anything interesting that the separate images did not do on their own. looks like they came to the same conclusion.
I thought the same about an old-vs-new comparison of the classic Pillars of Creation image, though on a second look they are both stunning in their own ways.
You know the story about IR cameras that can see through clothes, it is mostly a myth but there is some truth to it as some clothes are transparent in infrared.
Same idea here, with the deeper IR Webb operates on, you get to see the galaxy "naked", which is great if you want to study its anatomy. But not everyone enjoys seeing naked galaxies.
You're thinking of a nebula. That’s the remnants of a supernova. A galaxy is an unimaginably large collection of stars. A nebula is still quite large, but several orders of magnitude smaller than a galaxy.
"Unlike the Milky Way and Andromeda galaxies, the Triangulum Galaxy does not appear to have a supermassive black hole at its center. This may be because the mass of a galaxy's central supermassive black hole correlates with the size of the galaxy's central bulge, and unlike the Milky Way and Andromeda, the Triangulum Galaxy is a pure disk galaxy with no bulge."
Triangulum is a spiral galaxy in our local group, perhaps bound to Andromeda or us.
In the sibling photo in the index is a comparison of Hubble vs Webb.
Hubble is very brown-y, and Webb is much more blue.
But these are false colors, and they capture different light. It has to be an artistic decision to make it blue, vs brown, so does anyone here know the rationale? Is it to distinguish the different provenance? Is the color shift indicative of the captured spectrum difference? Is it a convention of the sensor? Is it a 2020s fad?
> These images are a composite of separate exposures acquired by the James Webb Space Telescope using the MIRI instrument. Several filters were used to sample wide wavelength ranges. The color results from assigning different hues (colors) to each monochromatic (grayscale) image associated with an individual filter. In this case, the assigned colors are: Blue: F770W, Green: F1130W, Red: F1280W.
Chasing some numbers up, it looks like they've made the wavelengths around 20 times shorter to bring the picture into the visible spectrum.
It's not arbitrary. They assign colours in order based on wavelength, so the shortest wavelengths will be bluer and the longest wavelengths will be redder.
mid near infrared vs visible light. one of the big bets with webb is that visible isn't the ideal spectrum to target. it's fantastic from a research standpoint but the pictures may seem less pleasing vs hubbles.
At a rough 10 trillion kms = 1 light year,
Sombrero galaxy is 31.1 million light years away,
1 quadrillion kms = 100 light years,
1 quintillion kms = 100,000 light years,
100 quintillion km = 10 million light years,
so basically we are looking at an object 300 quintillion kms away
At this fraction of light speed 0.99999999999999999999 to the person inside the spaceship only 1.6 days will pass. But to a person on earth, it would be 31.1 million light years. Crazy eh?
Not hugely crazy, it's a function that asymptotically approaches infinity.
If you want crazy effects, IIRC the relativistic time dilation factor is also the temperature dilation factor, which means at that speed the cosmic microwave background radiation will cause positron-electron pair production in the hull of the spaceship, to a depth that is dependent on how effectively it blocks extremely hard gamna rays — like, if you're in a space suit, it will be throughout your entire body because neither the suit nor your bones are particularly opaque at that energy level.
It sort of does to me - disks made up of concentric orbits are have no intersections, and so collisions are less likely. In a ball, debris would have different directional vectors that would eventually collide with one another. The disk is the stable evolution of that state.
I believe it's not that collisions (and gravitational interactions) don't happen when it's in a disk, but the galaxy as a whole has an overall rotational momentum about some axis, and collisions within the galaxy can't change that. This means that it can flatten along the axis, but it can't shrink in the perpendicular plane.
If everything were twice as close to the axis (as gravity would like it to be), it would need to be moving twice as fast to conserve rotational momentum, but that's faster than the velocity of a circular orbit at the new radius (assuming everything was in a circular orbits to begin with).
The same principle is why almost everything in the solar system approximately lies within a plane.
Because galaxies spin. A spinning ball will compress into a disc after a while.
The parts which are close to the axis just fall into the middle and some amount of friction slows them down until they stay close to the plane.
Unrelated- but exists there a fast forward- projected position of the sky- as it would be actually toady? Like a rendered simulation without a million year timelag?
45 comments
[ 3.3 ms ] story [ 76.6 ms ] threadhttps://science.nasa.gov/mission/hubble/science/explore-the-...
It is interesting seeing past the central portion to see the complete rings on the back side. In the MIRI image, it looks like a special FX shot from some scifi where the explosion happens on a plane rather than a sphere.
https://webbtelescope.org/contents/media/images/2022/052/01G...
Same idea here, with the deeper IR Webb operates on, you get to see the galaxy "naked", which is great if you want to study its anatomy. But not everyone enjoys seeing naked galaxies.
"Unlike the Milky Way and Andromeda galaxies, the Triangulum Galaxy does not appear to have a supermassive black hole at its center. This may be because the mass of a galaxy's central supermassive black hole correlates with the size of the galaxy's central bulge, and unlike the Milky Way and Andromeda, the Triangulum Galaxy is a pure disk galaxy with no bulge."
Triangulum is a spiral galaxy in our local group, perhaps bound to Andromeda or us.
https://en.wikipedia.org/wiki/Triangulum_Galaxy
A fun game would be to make a post like yours and then find the fewest degrees of Kevin Bacon to get back to TFA.
Hubble is very brown-y, and Webb is much more blue.
But these are false colors, and they capture different light. It has to be an artistic decision to make it blue, vs brown, so does anyone here know the rationale? Is it to distinguish the different provenance? Is the color shift indicative of the captured spectrum difference? Is it a convention of the sensor? Is it a 2020s fad?
> These images are a composite of separate exposures acquired by the James Webb Space Telescope using the MIRI instrument. Several filters were used to sample wide wavelength ranges. The color results from assigning different hues (colors) to each monochromatic (grayscale) image associated with an individual filter. In this case, the assigned colors are: Blue: F770W, Green: F1130W, Red: F1280W.
Chasing some numbers up, it looks like they've made the wavelengths around 20 times shorter to bring the picture into the visible spectrum.
Hubble uses visible light and I prefer this image from an artistic standpoint as it seems to capture depth better.
If you want crazy effects, IIRC the relativistic time dilation factor is also the temperature dilation factor, which means at that speed the cosmic microwave background radiation will cause positron-electron pair production in the hull of the spaceship, to a depth that is dependent on how effectively it blocks extremely hard gamna rays — like, if you're in a space suit, it will be throughout your entire body because neither the suit nor your bones are particularly opaque at that energy level.
If everything were twice as close to the axis (as gravity would like it to be), it would need to be moving twice as fast to conserve rotational momentum, but that's faster than the velocity of a circular orbit at the new radius (assuming everything was in a circular orbits to begin with).
The same principle is why almost everything in the solar system approximately lies within a plane.
Those further out would tend to collapse towards the equator and eventually that initial ball would become more disk shaped.
Then there is this explanation refering to the conservation of angular momentum: https://van.physics.illinois.edu/ask/listing/18318
https://en.wikipedia.org/wiki/Elliptical_galaxy