Justin Hunt
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Sterile neutrinos are pretty much the last harrah of WIMPs, most early WIMP theories were looking at SuSy particles, and those hopes started fading away after the LHC started reducing the places where SuSy can hide. Sterile neutrinos weren't even expected to produce enough mass to account for all of Dark Matter, originally they only expected enough sterile neutrinos to fill out a bit of the DM picture, mostly filled by SuSy. Now they're going to have to not only discover sterile neutrinos, but also to find enough of it to fill out the entire DM universe.Bandersnatch said:Neutrinos exist. Granted, the examples that are known to exist are lighter than the types we're talking about...
Being primordial BH's, they wouldn't be born from stars like stellar mass BH's are. They would've been born in the high pressures and temperatures of the Big Bang itself. So no, they wouldn't be stellar mass BH's just shrunk down due to Hawking Radiation (that would take multi-trillions of years). The PBH's would have been born immediately after the Big Bang, as mass and energy densities within the plasma would've been high enough to create instantaneous BH regions. It is also expected that these PBH's would've been formed at widely-varied scales, not just the stellar mass kind. They could've been created at ranges as low as asteroid-mass all of the way upto supermassive-class BH's. In fact, I would say the most likely origin of galactic supermassive BH's is primordial rather than the merger of millions of stellar BH's.Justin Hunt said:@bbbl67 PBH are just as farfetched as WIMPS. We have no proof that PBH exist, are stable, or can even be formed. Assuming hawking radiation is correct, there has not been enough time for stellar BHs to have shrunken to that size nor would micro BH been able to grow to that size.
Unfalsifiable statements usually are irrefutable.bbbl67 said:I think it's nearly irrefutable that all supermassive BH's are PBH's.
This is not correct and does not describe PBH formation in an accurate way. Very simplified, PBHs may form when density perturbations reenter the horizon such that the Schwarzschild radius of the mass contained within one Hubble radius exceeds the Hubble radius itself. This would happen in the very early universe and there would not be any question of compressing mass.Justin Hunt said:Whatever the reason is, I would imagine this is what would also prevent PBH from actually forming below stellar masses and even if they did, it is quite possible they would simply expand back out again similar to what happens when you release a stress ball.
You seem to here be implying that there would be no dark matter. This is not the case. In fact, what you are describing is the standard production of thermal dark matter where the final density is set by when the interaction rate falls below the Hubble rate. This happens sooner for particles that do not interact very strongly with each other.Ian J Miller said:When matter and antimatter self-annihilated but for an asymmetry that left us with an excess of matter, these fermions would not do that.
This depends very much on the mass range that you are looking in. Standard WIMP scenarios where you search using direct detection experiments go down to a few GeV, which is needed to produce an appreciable recoil in the experiment. The exact search strategy would depend on the type of interactions that the DM has - you would need to specify your model further - but in general it can indeed be very hard.Ian J Miller said:how would you detect them given they do not interact electromagnetically, they do not clump and they do not decay to anything? In my opinion, not easily, and not with detectors looking for much more massive particles.
BillKet said:I was wondering what the Physics Forums community thinks about this lack of evidence for DM despite numerous and different approaches to find it (DAMA/LIBRA experiment claims to have found it, but no one was able to reproduce their results).
Dale said:I wouldn’t rush to get rid of DM. It has been observed gravitationally and looks like it doesn’t interact much otherwise. So it will be inherently difficult to detect.
None of the posts have mentioned the evidence for the existence of DM as non-baryon stuff based on the abundance of deuterium created during the period of primordial Nucleosynthesis.bbbl67 said:Sterile neutrinos are pretty much the last harrah of WIMPs, most early WIMP theories were looking at SuSy particles, and those hopes started fading away after the LHC started reducing the places where SuSy can hide.
The discussion of this point seems to assume that PBHs (if they exist) consist entirely of DM. However, one would expect that only 85.5% of a BH's mass would be DM.Orodruin said:Primordial black holes are actively discussed in the dark matter community and mostly ruled out by different experiments depending on the mass range.
Huh? This is not correct. The PBHs would be the dark matter.Buzz Bloom said:The discussion of this point seems to assume that PBHs (if they exist) consist entirely of DM. However, one would expect that only 85.5% of a BH's mass would be DM.
Hi Orodruin:Orodruin said:Huh? This is not correct. The PBHs would be the dark matter.
How they formed is completely irrelevant. The black holes are dark matter in this scenario, there is no "other" dark matter to capture.Buzz Bloom said:If you are correct about this, then I must have a wrong view about quite a few topics. I would much appreciate it if you would post an explanation of how a PBH would form without any baryonic matter being captured along with the DM.
Hi Orodruin:Orodruin said:How they formed is completely irrelevant. The black holes are dark matter in this scenario, there is no "other" dark matter to capture.
In what sense is a PBH collision-less or nearly so? Why does not ordinary matter constantly collide with a PBH event horizon and become additional mass of the PBH?Buzz Bloom said:I still do not understand, "they are (nearly) collision-less".
We know it doesn't influence the light going through apart from its gravitational effect - otherwise it would be part of the regular matter.Sanborn Chase said:Does it matter that all of our celestial observations since the beginning of time have been through a filter the substance of which we know next to nothing?
Sanborn Chase said:I'm extremely buoyed by your confidence.
Dale said:MOND is not a viable alternative, regardless of any perceived problems with DM.
I wouldn’t rush to get rid of DM. It has been observed gravitationally and looks like it doesn’t interact much otherwise. So it will be inherently difficult to detect.
Science isn’t room service where you can order a result to your liking to be delivered by the end of the sitcom you are watching. It is a difficult enterprise and honest science always has a real risk of null results.
bbbl67 said:So to answer your question about whether we've found evidence of PBH's? I think it's nearly irrefutable that all supermassive BH's are PBH's. But we haven't found evidence for sub-stellar mass PBH's yet though.
Justin Hunt said:@bbbl67My point is that almost every one of these quantities has a degree of uncertainty to it. So, couldn't part of the issue be compounded issues of uncertainty when we look at galactic distances? In order to determine the rotation curves, we had to determine the mass of the visible matter, we had to determine the velocities stars etc, none of which can be directly observed.
Maybe there are WIMPS, maybe there are PBH, maybe our understanding of gravity is complete etc. or maybe it is a combination of more than one of those things. At the very least, an AI algorithm could be used to determine the most likely candidates.
Perhaps. I admittedly have not followed any recent developments of MOND, having examined them and lost interest in them quite some time ago. It could be that something new has overcome previous problems.ohwilleke said:This profoundly overstates the case