EDIT: Let’s cool it with the downvotes, dudes. We’re not out to cut funding to your black hole detection chamber or revoke the degrees of chiropractors just because a couple of us don’t believe in it, okay? Chill out, participate with the prompt and continue with having a nice day. I’m sure almost everybody has something to add.
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Do you think solutions to dark matter are tied up in a unified GR + quantum mechanics theory?
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That sounds like it’s trying to take large scale phenomena and make them work on the quantum scale. What if the solution is the other way around: make modified quantum mechanics work on the large scale? (I guess those are effectively the same thing. You’d need a quantum gravity theory one way or another. Sorry, layman here. Just spitballin’ ideas)
The experimental observation did not reveal Dark Matter. Nobody has seen or proven Dark Matter, actually. That’s why it is called Dark Matter. The observation just showed that the math model was flawed, and they invented “Dark Matter” to make up for it.
My personal take is that they will one day add the right correction factor that should have been in the fomulas all the time.
Just like with E=mc² not being completely correct. It’s actually E²=m²c⁴ + p²c². The p²c² is not adding much, but it is still there.
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I know that it is not a simple scale thing here. So it might be something else. My bet is that is has something to do with angular momentum,
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I’m no astrophysicist - I just design computer chips. But this issue of “We need dark matter” came up with rotating galaxies, didn’t it? So I’d look into that direction if there is a potential connection. Classic bug hunting technique.
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Sounds like the retired engineer that has a theory cliché.
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No, I’m just wondering about the reasoning for something that has not been observed except for it’s gravity effects. I mean, physics has loads of incomplete models, so for me, just another incomplete model looks more likely than some phantom particles that nobody can explain.
The Bullet Cluster, among several other systems, are very strong evidence that dark matter is actual baryonic matter that does not experience significant (or any) electromagnetic interactions. What we see when we look at these kinds of systems is that there is all evidence of STUFF there, but we cannot see the stuff. It’s not an indication of a poorly-performing math model missing a function term.
It would be like if we saw ripples in the water like we know exist around a rock. But we don’t see a rock. Sure, MAYBE we just fundamentally need to rewrite our basic rules of fluid mechanics to be able to create these exact ripples. But the more probable explanation is that there’s a rock we can’t see, and falsifying that theory will require just HEAPS of evidence.
The evidence we have suggests overwhelmingly that there is actual stuff that has mass that we simply do not have the tools to observe. Which isn’t all that surprising given that we are only JUST starting to build instruments to observe cosmological phenomena using stuff other than photons of light.
How would you know the difference? All the evidence of “STUFF” being there is obviously gravity based, as no other factors are involved. So that “STUFF” has a number of parameters that can be determined from the postulation of it’s existence: It should be baryonic to have the mass, and it should be stable, or one would probably observe energetic events related to state changes. Another point is: if it has mass, why does it not just clump together? I guess one can also rule out that it is charged, or one might see electromagnetic interactions. Did I miss a key parameter? Did I misunderstand anything here?
So do you know of any 3 (or maybe even 5 or 7) quarks baryon that would fit the pattern? The amount of combinations is limited, and CERN and others have created so many different particles over time that something of that kind that is actually stable should have made an appearance? Or are there any theoretical works on what kind of particle this could be, matching the pattern?
And, by the way, I would not call it a “poor performing” math model, as it covers quite a lot of the world we can observe. I deliberately used the term “incomplete”.
We observe patterns of behavior – orbits, movement, gravitational lensing – that are exactly what we would see if, for example, there were great clouds of matter or other galaxies in those places. But we don’t see the hydrogen gas. We see non-uniform distributions of dark matter mass that imply there is not simply some consistent calculation error, but rather that there is dark matter that is not uniformly distributed. Again, read up on the Bullet Cluster because it shows a VERY clear example of what I am talking about, where the regular, electromagnetically-interacting matter behaves one way but the apparent shadow of dark matter behaves in a different way that is consistent with lack of electromagnetic interactions.
We’ve also discovered things like ultradiffiuse galaxies – likely remnants from ancient collisions – that have apparently been stripped of their dark matter. MOND cannot explain these observations because these galaxies essentially behave in a Newtonian manner that would be impossible in a MOND framework.
Why does stuff clump together? For all non-dark matter, the answer is electromagnetism. Outside of the extreme cases of neutron stars and black holes, where gravity overwhelms and defeats electromagnetism and the nuclear forces theoretically take over to create degeneracy pressure, electromagnetism is the reason things clump. Absent electromagnetism, what would cause clumping? Essentially nothing, stuff would whizz straight through other stuff and go into orbits. Potentially HUGE orbits, which is why there’s so many theories around dark matter “halos”. Maybe if there were DIRECT collisions of theoretical DM particles, that might cause an energy-releasing event – this is one of the things current dark matter detectors are looking for and may yet find within the upcoming years.
Yep, and more than a handful Many that make specific predictions we can test for and so are testing for. For example, you could look at axions, which are a theoretical particle predicted by an entirely different theory that may be a good fit for the dark matter particle.