ibysaiyan said:Welcome to PF TheBlackNinja !
One of the ways in which we assume the presence of dark matter is by the effect it has over the rotational velocity of spiral/elliptical galaxies (I think).When we plot a graph of rotational curve of a particular galaxy against the distance from the centre of the galactic bulge(I think you might have mis-interpreted galactic center to age,maybe).
What we observe is that near the proximity of visible galaxy the rotational velocity values for the i) Observed and ii) expected value appear to be very similar i.e negligible difference but as we go further away from the center to our surprise we note the expected value to be constant(why is it constant for the density is decreasing).This is where the mysterious,hypothetical matter comes into the picture.
At lower radius we get the relation of 'v' proportional to 'r' but on high radius we see 'v' proportional to 'r^-1/2' .
EDIT:As for the expected values,we get them by taking into consideration the whole baryonic matter ,the micro waves given off by the neutral hydrogen clouds,etc.
Regards,
ibysaiyan
TheBlackNinja said:I think I had understood that before, but I was just thinking that this "thing"(which they define as an non observable matter) may have have some typical dynamic.Like, its distribution inside the galaxy may change over the time.So I was thinking that observing galaxies at different ages could give some clue.
I had actually thought about lots of black holes before, because I had read the the youngest spiral galaxies had mostly O and B stars, and as they die fast they'd probably be black holes now.So in those young galaxies the rotation curve would be as expected, since they don't have those numerous black holes yet.
TheBlackNinja said:Hi there! thanks for the reply and the welcomes
you seem to have swapped "observed" with "expected" where I highlighted.
I think I had understood that before, but I was just thinking that this "thing"(which they define as an non observable matter) may have have some typical dynamic.Like, its distribution inside the galaxy may change over the time.So I was thinking that observing galaxies at different ages could give some clue.
I had actually thought about lots of black holes before, because I had read the the youngest spiral galaxies had mostly O and B stars, and as they die fast they'd probably be black holes now.So in those young galaxies the rotation curve would be as expected, since they don't have those numerous black holes yet.
This idea may be naive but it should help to explain what I think.Maybe whatever is that dark matter was not dark at some instant, or it was not distributed that way that gives that characteristic rotation curve, or something like that
That's right. In fact, very very few starts collapse directly into a black hole. The most promising mechanism is you have a medium-mass star (~15-20 solar masses) which collapses into a neutron star with a companion nearby. Then you slowly accrete gas until you pass the TOV limit and collapse to a BH. It's really difficult to do without a companion, since to directly collapse into a BH you need something ~100 solar masses.ibysaiyan said:I was under the impression that not all stars transit into black holes(For the super giants once it has gone through type II supernovae the leftover remnant /core becomes a neutron star,which further collapses only if the Tolman Oppenheimer-volkoff limit is surpassed
also not all black holes survive,they evaporate too due to entropy(I might be wrong).
ibysaiyan
Nabeshin said:That's right. In fact, very very few starts collapse directly into a black hole. The most promising mechanism is you have a medium-mass star (~15-20 solar masses) which collapses into a neutron star with a companion nearby. Then you slowly accrete gas until you pass the TOV limit and collapse to a BH. It's really difficult to do without a companion, since to directly collapse into a BH you need something ~100 solar masses. While it is true that black holes evaporate, any that have formed as a result of stellar collapse must have roughly stellar masses (take 1 solar mass). The lifetime for a black hole this size is many orders of magnitude large than the current age of the universe (Not to mention the fact that the CMB alone provides more than enough of an energy influx to counteract the radiation). So evaporation is not an issue for stellar mass holes -- only very small black holes have this problem.
Galactic rotation curves are graphical representations of the rotation speed of stars or gas within a galaxy as a function of their distance from the center of the galaxy. They can help us understand the distribution of mass within a galaxy.
Galactic rotation curves are important because they provide evidence for the existence of dark matter, as they show that the observed rotation speeds of stars and gas do not match the predicted speeds based on the visible mass in a galaxy.
Galactic rotation curves are measured by observing the Doppler shifts of light emitted by stars or gas at different distances from the center of a galaxy. These shifts can then be used to calculate the speed of rotation at each distance.
Galactic rotation curves tell us that galaxies have a significant amount of mass distributed throughout their entire volume, rather than just concentrated in the center as was previously thought. This supports the theory of dark matter and suggests that galaxies have a more complex structure than we initially thought.
Galactic rotation curves have a significant impact on our understanding of the universe as they provide evidence for the existence of dark matter, which makes up a large portion of the total matter in the universe. They also challenge our current understanding of galaxy formation and evolution, leading to the development of new theories and models.