Simon Bridge said:If I have understood what you are getting at:
That's already accounted for as binding energy and mass for the protons and neutrons and etc.
Such particles wouldn't cluster like dark matter does. Clustering requires them to be persistent.dryogeshd said:Hi all,
I was wondering, could the dark matter just be the particles that actually pop in and out of existence inside the protons and neutrons and all other matter or anti-matter?
Please enlighten me if my assumption is wrong somewhere.
ryanuser said:I was thinking that dark matter even isn't matter, its a force because apparently it might be interacting with gravity and gravity is a force.
ryanuser said:Dryogeshd it self has given his/her idea, you are allowed to discuss and give your own reference to the question.
ryanuser said:Is the question by itself supportable?
Are all theories SUPPORTABLE?
ryanuser said:Comment on the statement
ryanuser said:I was thinking that dark matter even isn't matter, its a force because apparently it might be interacting with gravity and gravity is a force.
ryanuser said:So how about gravity, that's not a particle, is it? Its the curvature of space-time which acts on particles and other matters.
If it isn't matter how does it interact gravitationally? You seem to be really confused about this. There are numerous articles available about dark matter. Why don't you study up on it a bit?I was thinking that dark matter even isn't matter
ryanuser said:So how about gravity, that's not a particle, is it? Its the curvature of space-time which acts on particles and other matters.
Well, that's not quite true. The strong nuclear force acts on itself (in a sense: gluons carry strong force charges). This is why the strong nuclear force is a short-range force. Obviously a similar thing can't really be happening with dark matter for its impact to stretch across millions of light years.Drakkith said:Forces act upon particles, so no, dark matter itself is not a force. Realize that there are no forces that act upon other forces. None of the 4 fundamental forces of nature interact with each other in any way. They act solely upon the particles themselves.
... so you are thinking that either 1. there is something else out there that puts an additional curvature to space-time, or 2. that gravity just does not behave the way we think over long distances?ryanuser said:So how about gravity, that's not a particle, is it? Its the curvature of space-time which acts on particles and other matters.
+1 :)Chalnoth said:But regardless, the idea that somehow dark matter might be a modification of gravity, or something else that acts sort of like gravity, is very hard to support these days.
dryogeshd said:Hi all, Thank you so much for participating, Essentially, what I understand till now is that, dark matter is thought to be clumped in some places causing gravitational lensing, are these gravitational lenses located precisely around galaxies/black holes? or are they also distributed in the intergalactic space as well? If they are in the same positions as the galaxies, then it is probable that unaccounted for mass is within the matter that we measure in these galaxies... That implies we are missing a rather important particle/s that is contributing to the mass on the universe.
There is a relationship with normal matter, but it isn't perfect. Read the blog post I linked above, as it highlights a case where the normal matter was separated from the dark matter due to a collision.dryogeshd said:Hi all, Thank you so much for participating, Essentially, what I understand till now is that, dark matter is thought to be clumped in some places causing gravitational lensing, are these gravitational lenses located precisely around galaxies/black holes? or are they also distributed in the intergalactic space as well? If they are in the same positions as the galaxies, then it is probable that unaccounted for mass is within the matter that we measure in these galaxies... That implies we are missing a rather important particle/s that is contributing to the mass on the universe.
Simon Bridge said:The satellite galaxies are well studied objects.
That report was from 2009 ... how about something more recent?
The dwarf spheroidal satellite galaxies of the Milky Way are some of the most dark-matter-dominated objects known. Due to their proximity, high dark matter content, and lack of astrophysical backgrounds, dwarf spheroidal galaxies are widely considered to be among the most promising targets for the indirect detection of dark matter via gamma rays.
##\qquad## http://arxiv.org/abs/1310.0828 (Oct. 2013)
More accessible: Scientific American, Oct 2013.
http://www.scientificamerican.com/article.cfm?id=milky-way-satellite-dwarf-galaxies
As for why some scientists, yea even unto the astrophysicists, disagree with standard models ... that's because it's their job.
A model stands not on the amount of evidence in it's favor but on the cleverness of the failed efforts to refute it.
There's no such thing as 100% proof. But it is compelling evidence that makes MOND-type theories hard to support. The CMB is even more compelling evidence, but that's a little bit more difficult to wrap your head around as to precisely why.kye said:Is the collision separation phenomenon 100% proof of dark matter? if so, why is that some scientists still doubt their existence.. even astrophysicists... and they even have data that suggest it is opposite to dark matter predictions. see:
http://www.sciencedaily.com/releases/2009/05/090505061949.htm
any familiar with what they are talking about?
The claim here still requires a form of dark matter to fit the data. In this case, they use an undetected heavy species of neutrino in the fit (we know the three neutrinos we know about can't have that much mass). So they have a much more complicated model than just having dark matter: they've got both dark matter and modified gravity. Occam's Razor suggests that this is rather unlikely.kye said:Here's more recent the suggest MOND is more appropriate.. so how does it still support dark matter?
http://www.sciencedaily.com/releases/2011/02/110223092406.htm
Dark matter is a hypothetical type of matter that is thought to make up about 85% of the total matter in the universe. It does not emit or absorb light, making it invisible to telescopes and other instruments used to study the universe. Its existence is inferred through its gravitational effects on visible matter.
Dark matter plays a crucial role in the formation and evolution of galaxies, as well as the large-scale structure of the universe. It also helps to explain discrepancies in the observed rotation of galaxies and the amount of visible matter present. Understanding dark matter is essential in our quest to fully understand the universe and its origins.
There are several theories about what dark matter could be made of, but the most widely accepted hypothesis is that it is composed of a type of particle that interacts very weakly with ordinary matter. These particles are collectively referred to as Weakly Interacting Massive Particles (WIMPs).
Dark matter differs from regular matter in several ways. It does not interact with light, making it invisible, and it does not interact strongly with other particles, meaning it does not emit or absorb electromagnetic radiation. It also does not form atoms or molecules like regular matter does.
Scientists are using a variety of methods to try and detect dark matter. These include using large underground detectors to capture any interactions between dark matter particles and ordinary matter, searching for signals from dark matter annihilation in space, and studying the effects of dark matter on the rotation of galaxies and the bending of light in gravitational lensing.