by Ann » Tue Apr 12, 2022 9:58 am
VictorBorun wrote: ↑Tue Apr 12, 2022 6:58 am
VictorBorun wrote: ↑Tue Apr 12, 2022 6:57 am
Do I get it right?
When we see some short-living blue giants in a red glowing bubble of α Hydrogen, what we see is a place of the gravitational collapse of a compressed area in cold transparent media of Hydrogen + dopes.
Here this media belongs to the Large Magellanic Cloud and is
orbiting Milky Way at 378 km/s and spins around the core of the LMC at 70 km/s or less, but the space around Milky Way is so empty that this gas remains cold and transparent until a gravitational compression starts at one place or other?
Not sure exactly what you mean, Victor.
The emission nebula IC 5146, better known as the Cocoon Nebula, is an example of an emission nebula, a red-glowing cloud of ionized hydrogen surrounding a small cluster and its dominant blue (but dust-reddened) star BD +46 3474. I don't know if the gas here is particularly "cold", not compared with its surroundings.
The red hydrogen gas is not collapsing. However, the fact that there is a cluster here at all is proof that there used to be a thick cloud of gas and dust where we now see the nebula and the cluster. The cluster was born when the gas and dust of this cloud contracted. We now see the remnants of that cloud, which itself was a part of a long cosmic dust lane.
Gas and dust has to contract in order to initiate star formation. And once a star has formed, its core will eventually grow more and more compact under the influence of gravity at the same time as the star is running out of fuel to sustain itself. The core of stars like the Sun will contract to the size of about the Earth as the Sun turns into a white dwarf. Stars of more than 8 solar masses normally turn into neutron stars the size of a large city like New York. Only the cores of the most massive stars turn into black holes.
The strong stellar wind of hot massive stars blow away the red nebulas. That is why we see no nebulosity around the massive circa 12 million year old
Double Cluster in Perseus. So the red hydrogen gas is actually being scattered away by the stars that make them glow red in the first place.
Click to play embedded YouTube video.
As for runaway stars, take a look at the Youtube video of a simulation of the formation of a globular star cluster. At 0.32, a star is being slingshotted out of the cluster. What happened? Well, the star was a member of a binary that came to close to another star, a single or a binary star. One component of the binary was captured by the other star, while the other component of the binary got a huge kick in the opposite direction, out of the cluster.
It takes a major kick indeed for a star to get kicked out of the Milky Way altogether, but if a binary star gets too close to, say, the central black hole of the Milky Way, then it can happen.
It is possible that a supernova can also send a star flying out of its galaxy. It is much more likely that this will happen to stars in the Large Magellanic Cloud than to stars in the Milky Way, because the gravity of the LMC is so much lower than the gravity of the Milky Way. And in any case, there are lots and lots of pairs of very massive LMC stars that can interact with one another so that one component is sent flying.
Ann
[quote=VictorBorun post_id=322025 time=1649746737 user_id=145500]
[quote=VictorBorun post_id=322024 time=1649746678 user_id=145500]
Do I get it right?
When we see some short-living blue giants in a red glowing bubble of α Hydrogen, what we see is a place of the gravitational collapse of a compressed area in cold transparent media of Hydrogen + dopes.
Here this media belongs to the Large Magellanic Cloud and is [url="https://academic.oup.com/mnras/article/469/2/2151/3573852"]orbiting Milky Way at 378 km/s[/url] and spins around the core of the LMC at 70 km/s or less, but the space around Milky Way is so empty that this gas remains cold and transparent until a gravitational compression starts at one place or other?
[/quote]
[/quote]
Not sure exactly what you mean, Victor.
[float=left][img3="Emission nebula IC 5146 surrounding cluster Collinder 470 and ionizing star BD +46 3474. Photo: Adam Block."]https://upload.wikimedia.org/wikipedia/commons/9/9d/Ic5146s.jpg[/img3][/float][float=right][img3="Widefield image of IC 5146, the Cocoon Nebula. You can see that the Cocoon Nebula appears to have formed at the tip of a long cosmic dust lane. Photo: Keesscherer at English Wikipedia."]https://upload.wikimedia.org/wikipedia/commons/thumb/8/8c/IC5146_The_Cocoon_Nebula.jpg/1024px-IC5146_The_Cocoon_Nebula.jpg[/img3][/float]
[clear][/clear]
The emission nebula IC 5146, better known as the Cocoon Nebula, is an example of an emission nebula, a red-glowing cloud of ionized hydrogen surrounding a small cluster and its dominant blue (but dust-reddened) star BD +46 3474. I don't know if the gas here is particularly "cold", not compared with its surroundings.
The red hydrogen gas is not collapsing. However, the fact that there is a cluster here at all is proof that there used to be a thick cloud of gas and dust where we now see the nebula and the cluster. The cluster was born when the gas and dust of this cloud contracted. We now see the remnants of that cloud, which itself was a part of a long cosmic dust lane.
Gas and dust has to contract in order to initiate star formation. And once a star has formed, its core will eventually grow more and more compact under the influence of gravity at the same time as the star is running out of fuel to sustain itself. The core of stars like the Sun will contract to the size of about the Earth as the Sun turns into a white dwarf. Stars of more than 8 solar masses normally turn into neutron stars the size of a large city like New York. Only the cores of the most massive stars turn into black holes.
The strong stellar wind of hot massive stars blow away the red nebulas. That is why we see no nebulosity around the massive circa 12 million year old [url=https://en.wikipedia.org/wiki/Double_Cluster#/media/File:Double_Cluster.jpg]Double Cluster in Perseus[/url]. So the red hydrogen gas is actually being scattered away by the stars that make them glow red in the first place.
[float=right][youtube]https://www.youtube.com/watch?v=E8nw2x6YV0A[/youtube][/float]As for runaway stars, take a look at the Youtube video of a simulation of the formation of a globular star cluster. At 0.32, a star is being slingshotted out of the cluster. What happened? Well, the star was a member of a binary that came to close to another star, a single or a binary star. One component of the binary was captured by the other star, while the other component of the binary got a huge kick in the opposite direction, out of the cluster.
It takes a major kick indeed for a star to get kicked out of the Milky Way altogether, but if a binary star gets too close to, say, the central black hole of the Milky Way, then it can happen.
It is possible that a supernova can also send a star flying out of its galaxy. It is much more likely that this will happen to stars in the Large Magellanic Cloud than to stars in the Milky Way, because the gravity of the LMC is so much lower than the gravity of the Milky Way. And in any case, there are lots and lots of pairs of very massive LMC stars that can interact with one another so that one component is sent flying.
Ann