Starship Asterisk*

Fred the Cat wrote: ↑Sun Oct 07, 2018 11:23 pm

Chris Peterson wrote: ↑Thu Oct 04, 2018 4:03 am

Fred the Cat wrote: ↑Thu Oct 04, 2018 2:16 am
Nor in the core of an atom though I might suspect its halo. If it doesn’t interact with ordinary matter perhaps it does share the same space. Sorry I have no evidence, but any space does seem to have unusual properties whether in atoms or galaxies.

But dark matter does interact with ordinary matter.

Interact may have been the wrong word. Containment might have been more appropriate. One type for the strong force and quarks and another for electro-magnetism and the weak force. And possibly another for gravity on a larger scale. Wild conjecture but I can help myself in imagining how the "dark" could relate to the universe in all its variety of size dimensions. :ssmile:

Chris Peterson wrote: ↑Thu Oct 04, 2018 4:03 am

Fred the Cat wrote: ↑Thu Oct 04, 2018 2:16 am

Chris Peterson wrote: ↑Wed Oct 03, 2018 10:40 pm

All the evidence suggests that dark matter interacts exactly as we'd expect with ordinary matter. That is, gravity works the same with all massive bodies, regardless of other properties. Indeed, it is by observing the gravitational attraction between ordinary and dark matter that we know dark matter exists. Dark matter is just that- dark- because it doesn't interact with the electromagnetic force.

Since dark matter doesn't interact electromagnetically, there's no mechanism by which it could end up in the core of stars. Or in the core of galaxies. That's why we always see it as a halo. Presumably that's a huge number of particles which are individually in ordinary orbits around the combined center of mass of the ordinary/dark matter concentration.

Nor in the core of an atom though I might suspect its halo. If it doesn’t interact with ordinary matter perhaps it does share the same space. Sorry I have no evidence, but any space does seem to have unusual properties whether in atoms or galaxies.

But dark matter does interact with ordinary matter.

Chris Peterson wrote: ↑Thu Oct 04, 2018 1:29 pm

BDanielMayfield wrote: ↑Thu Oct 04, 2018 4:50 am We know that, if dark matter exists, it gravitationally attracts ordinary matter, but is the converse necessarily true? Does dark matter fall toward small scale ordinary masses like stars and black holes?

Yes. Dark matter and ordinary matter interact gravitationally exactly like ordinary matter with ordinary matter, and dark matter with dark matter. Dark matter has no "special" gravitational properties. It has mass, and acts like anything with mass.

It seems that it would have to if it were just some kind of a mass-only particle. I don't understand the statements "there's no mechanism by which it could end up in the core of stars. Or in the core of galaxies." What about the "mechanism" of gravity?

Gravity by itself cannot concentrate matter. In order for that to happen, you need to have a mechanism by which orbiting particles lose energy. Otherwise they remain in exactly the same orbit, not one that decays into the core of stars or galaxies. After all, our planets don't all fall into the core of the Sun (at least outside of any extremely long time scale). They simply orbit, and that's what the material in dark matter halos is doing. It only "falls into" massive things to the extent that it follows orbits around those masses. Why do we get stars out of ordinary matter? Because that matter interacts with other ordinary matter via the electromagnetic force. That is the origin of friction and viscosity and all the other damping mechanisms that rob particles in close proximity of angular momentum and allow them to spiral inwards. But dark matter lacks that, so there is no concentrating mechanism.

BDanielMayfield wrote: ↑Thu Oct 04, 2018 4:50 am

Chris Peterson wrote: ↑Wed Oct 03, 2018 10:40 pm
All the evidence suggests that dark matter interacts exactly as we'd expect with ordinary matter. That is, gravity works the same with all massive bodies, regardless of other properties. Indeed, it is by observing the gravitational attraction between ordinary and dark matter that we know dark matter exists. Dark matter is just that- dark- because it doesn't interact with the electromagnetic force.

Since dark matter doesn't interact electromagnetically, there's no mechanism by which it could end up in the core of stars. Or in the core of galaxies. That's why we always see it as a halo. Presumably that's a huge number of particles which are individually in ordinary orbits around the combined center of mass of the ordinary/dark matter concentration.

We know that, if dark matter exists, it gravitationally attracts ordinary matter, but is the converse necessarily true? Does dark matter fall toward small scale ordinary masses like stars and black holes?

It seems that it would have to if it were just some kind of a mass-only particle. I don't understand the statements "there's no mechanism by which it could end up in the core of stars. Or in the core of galaxies." What about the "mechanism" of gravity?

Chris Peterson wrote: ↑Wed Oct 03, 2018 10:40 pm

BDanielMayfield wrote: ↑Wed Oct 03, 2018 7:50 pm

suicidejunkie wrote: ↑Wed Oct 03, 2018 2:01 pm Being embedded in a galaxy there would be dark matter passing through them in general.

Probably true.

I'd ask how likely they are to hog enough of it to be detectable as a halo above the background.

Your question assumes that dark matter is gravitationally attracted to ordinary matter. Is that true? If it was, wouldn't a buildup of non reactive dark matter gum up the works inside the cores of stars

All the evidence suggests that dark matter interacts exactly as we'd expect with ordinary matter. That is, gravity works the same with all massive bodies, regardless of other properties. Indeed, it is by observing the gravitational attraction between ordinary and dark matter that we know dark matter exists. Dark matter is just that- dark- because it doesn't interact with the electromagnetic force.

Since dark matter doesn't interact electromagnetically, there's no mechanism by which it could end up in the core of stars. Or in the core of galaxies. That's why we always see it as a halo. Presumably that's a huge number of particles which are individually in ordinary orbits around the combined center of mass of the ordinary/dark matter concentration.

Chris Peterson wrote: ↑Wed Oct 03, 2018 10:40 pm

BDanielMayfield wrote: ↑Wed Oct 03, 2018 7:50 pm

suicidejunkie wrote: ↑Wed Oct 03, 2018 2:01 pm I'd ask how likely they are to hog enough of it to be detectable as a halo above the background.

Your question assumes that dark matter is gravitationally attracted to ordinary matter. Is that true? If it was, wouldn't a buildup of non reactive dark matter gum up the works inside the cores of stars?

All the evidence suggests that dark matter interacts exactly as we'd expect with ordinary matter. That is, gravity works the same with all massive bodies, regardless of other properties. Indeed, it is by observing the gravitational attraction between ordinary and dark matter that we know dark matter exists. Dark matter is just that- dark- because it doesn't interact with the electromagnetic force.

Since dark matter doesn't interact electromagnetically, there's no mechanism by which it could end up in the core of stars. Or in the core of galaxies. That's why we always see it as a halo. Presumably that's a huge number of particles which are individually in ordinary orbits around the combined center of mass of the ordinary/dark matter concentration.

Ann wrote: ↑Thu Oct 04, 2018 1:20 am

rodentooth wrote: ↑Wed Oct 03, 2018 6:57 pm Why are there only blue and red lights sended from the stars? why no green eg.?

In order to look green, the stars would have to have a strong peak in the green part of the spectrum.

Fred the Cat wrote: ↑Thu Oct 04, 2018 2:16 am

Chris Peterson wrote: ↑Wed Oct 03, 2018 10:40 pm

BDanielMayfield wrote: ↑Wed Oct 03, 2018 7:50 pm
Probably true.

Your question assumes that dark matter is gravitationally attracted to ordinary matter. Is that true? If it was, wouldn't a buildup of non reactive dark matter gum up the works inside the cores of stars.

All the evidence suggests that dark matter interacts exactly as we'd expect with ordinary matter. That is, gravity works the same with all massive bodies, regardless of other properties. Indeed, it is by observing the gravitational attraction between ordinary and dark matter that we know dark matter exists. Dark matter is just that- dark- because it doesn't interact with the electromagnetic force.

Since dark matter doesn't interact electromagnetically, there's no mechanism by which it could end up in the core of stars. Or in the core of galaxies. That's why we always see it as a halo. Presumably that's a huge number of particles which are individually in ordinary orbits around the combined center of mass of the ordinary/dark matter concentration.

Nor in the core of an atom though I might suspect its halo. If it doesn’t interact with ordinary matter perhaps it does share the same space. Sorry I have no evidence, but any space does seem to have unusual properties whether in atoms or galaxies.

Chris Peterson wrote: ↑Wed Oct 03, 2018 10:40 pm

BDanielMayfield wrote: ↑Wed Oct 03, 2018 7:50 pm

suicidejunkie wrote: ↑Wed Oct 03, 2018 2:01 pm Being embedded in a galaxy there would be dark matter passing through them in general.

Probably true.

I'd ask how likely they are to hog enough of it to be detectable as a halo above the background.

Your question assumes that dark matter is gravitationally attracted to ordinary matter. Is that true? If it was, wouldn't a buildup of non reactive dark matter gum up the works inside the cores of stars.

All the evidence suggests that dark matter interacts exactly as we'd expect with ordinary matter. That is, gravity works the same with all massive bodies, regardless of other properties. Indeed, it is by observing the gravitational attraction between ordinary and dark matter that we know dark matter exists. Dark matter is just that- dark- because it doesn't interact with the electromagnetic force.

Since dark matter doesn't interact electromagnetically, there's no mechanism by which it could end up in the core of stars. Or in the core of galaxies. That's why we always see it as a halo. Presumably that's a huge number of particles which are individually in ordinary orbits around the combined center of mass of the ordinary/dark matter concentration.

rodentooth wrote: ↑Wed Oct 03, 2018 6:57 pm Why are there only blue and red lights sended from the stars? why no green eg.?

BDanielMayfield wrote: ↑Wed Oct 03, 2018 7:50 pm

suicidejunkie wrote: ↑Wed Oct 03, 2018 2:01 pm Being embedded in a galaxy there would be dark matter passing through them in general.

Probably true.

I'd ask how likely they are to hog enough of it to be detectable as a halo above the background.

Your question assumes that dark matter is gravitationally attracted to ordinary matter. Is that true? If it was, wouldn't a buildup of non reactive dark matter gum up the works inside the cores of stars :?:

rodentooth wrote: ↑Wed Oct 03, 2018 6:57 pm Why are there only blue and red lights sended from the stars? why no green eg.?

suicidejunkie wrote: ↑Wed Oct 03, 2018 2:01 pm Being embedded in a galaxy there would be dark matter passing through them in general.

I'd ask how likely they are to hog enough of it to be detectable as a halo above the background.

Chris Peterson wrote: ↑Wed Oct 03, 2018 1:33 pm

heehaw wrote: ↑Wed Oct 03, 2018 9:30 am Why don't globular clusters have any dark matter in them? Everything else does!

Everything? Dark matter and galaxies appear to be strongly associated. Presumably that's a consequence of the mechanism by which galaxies formed, very likely seeded by dark matter. But we don't really know how globulars form, so the role of dark matter in that isn't understood, either. And a small percentage of globular clusters do appear to have dark matter halos.

heehaw wrote: ↑Wed Oct 03, 2018 9:30 am Why don't globular clusters have any dark matter in them? Everything else does!