Starship Asterisk*

beryllium732 wrote: ↑Tue Jun 04, 2024 4:05 pm

Chris Peterson wrote: ↑Tue Jun 04, 2024 12:48 pm

beryllium732 wrote: ↑Tue Jun 04, 2024 11:49 am What would happen with the solar system if we were within 20 lightyears from a wolf rayet star and the bubble was expanding into it?

Nothing. The bubble is a hard vacuum.

Ok I see that's cool to know! What if we replaced the Alpha Centauri system with a Wolf Rayet star would we be impacted?

Chris Peterson wrote: ↑Tue Jun 04, 2024 12:48 pm

beryllium732 wrote: ↑Tue Jun 04, 2024 11:49 am What would happen with the solar system if we were within 20 lightyears from a wolf rayet star and the bubble was expanding into it?

Nothing. The bubble is a hard vacuum.

beryllium732 wrote: ↑Tue Jun 04, 2024 11:49 am What would happen with the solar system if we were within 20 lightyears from a wolf rayet star and the bubble was expanding into it?

Chris Peterson wrote: ↑Sat Jun 01, 2024 4:15 pm

Rauf wrote: ↑Sat Jun 01, 2024 7:49 am

Ann wrote: ↑Sat Jun 01, 2024 4:43 am
Massive stars form from particularly large disks. It seems likely, at least to me, that large disks are more prone than smaller ones to fragmenting, thus creating massive stars that are born as binaries.

Thanks Ann. But what causes this fragmentations? Gravity from a nearby star, or a black hole? Or maybe radiation and wind from the original star?

The protostellar disk is a fluid. That means there are turbulence and friction and viscosity effects. I don't think "fragmentation" is quite the right way to look at it. Stir some cream into your coffee and you'll see secondary vortexes appear.

Christian G. wrote: ↑Sat Jun 01, 2024 4:56 pm Just in case this question was missed earlier (and if it wasn't but just inspired no comments, that's fine!) - are Wolf-Rayet stars the brightest of stars intrinsincally? Supposedly THE brightest star currently known is a Wolf-Rayet (R136a 1), but is it also the case with any Wolf-Rayet compared to stars of similar mass, even luminous blue variables?

Rauf wrote: ↑Sat Jun 01, 2024 7:49 am

Ann wrote: ↑Sat Jun 01, 2024 4:43 am
Massive stars form from particularly large disks. It seems likely, at least to me, that large disks are more prone than smaller ones to fragmenting, thus creating massive stars that are born as binaries.

Thanks Ann. But what causes this fragmentations? Gravity from a nearby star, or a black hole? Or maybe radiation and wind from the original star?

Chris Peterson wrote: ↑Fri May 31, 2024 11:21 pm

johnnydeep wrote: ↑Fri May 31, 2024 6:36 pm

Chris Peterson wrote: ↑Fri May 31, 2024 6:25 pm

It's complicated. W-R stars blow off a lot of material which often generates a local nebula, similar in some ways to a planetary nebula. But they can certainly exist within existing nebulas. I think we're seeing both of those here.

The "fingery" blue ring is clearly from the W-R star, but are you saying that the blue gas arc is likely at least partly gas from the W-R or, that only the ring material is and the arc is just nearby gas? (Though there may be nothing definitive here to prove it one way of the other.)

Since it's not really concentric with the star I'm inclined to guess it's a shock front created when material from the stellar wind hits the surrounding medium. But that really is just a hunch.

Rauf wrote: ↑Sat Jun 01, 2024 7:49 am

Ann wrote: ↑Sat Jun 01, 2024 4:43 am

Rauf wrote: ↑Fri May 31, 2024 2:10 pm

OK, so I ask: Why 85% of high mass stars are part of binary systems?

One answer probably has to do with the formation process of high-mass stars.

A binary star is in the process of forming as the disk around 'the first star' has fragmented. Credit: NRAO.

---

Spaceref.com wrote:

Thanks Ann. I have hard time understanding what are the possible causes for a stellar disk to fragment. Gravity a nearby star, or blackhole maybe? Or maybe the original star's radiation and wind?
Astronomers know that about half of all Sun-like stars are members of double or multiple-star systems, but have debated over how such systems are formed.

“The only way to resolve the debate is to observe very young stellar systems and catch them in the act of formation,” said John Tobin, of the National Radio Astronomy Observatory (NRAO). “That’s what we’ve done with the stars we observed, and we got valuable new clues from them,” he added.

Their new clues support the idea that double-star systems form when a disk of gas and dust whirling around one young star fragments, forming another new star in orbit with the first. Young stars that still are gathering matter from their surroundings form such disks, along with jet-like outflows rapidly propelling material in narrow beams perpendicular to the disk.

Massive stars form from particularly large disks. It seems likely, at least to me, that large disks are more prone than smaller ones to fragmenting, thus creating massive stars that are born as binaries.

Ann

Thanks Ann. But what causes this fragmentations? Gravity from a nearby star, or a black hole? Or maybe radiation and wind from the original star?

Ann wrote: ↑Sat Jun 01, 2024 4:43 am

Rauf wrote: ↑Fri May 31, 2024 2:10 pm

Chris Peterson wrote: ↑Fri May 31, 2024 2:07 pm

Given that something like 85% of high mass stars are part of binary systems, maybe the question to ask is why only 50% of WR stars are binaries?

OK, so I ask: Why 85% of high mass stars are part of binary systems?

One answer probably has to do with the formation process of high-mass stars.

A binary star is in the process of forming as the disk around 'the first star' has fragmented. Credit: NRAO.

---

Spaceref.com wrote:

Thanks Ann. I have hard time understanding what are the possible causes for a stellar disk to fragment. Gravity a nearby star, or blackhole maybe? Or maybe the original star's radiation and wind?
Astronomers know that about half of all Sun-like stars are members of double or multiple-star systems, but have debated over how such systems are formed.

“The only way to resolve the debate is to observe very young stellar systems and catch them in the act of formation,” said John Tobin, of the National Radio Astronomy Observatory (NRAO). “That’s what we’ve done with the stars we observed, and we got valuable new clues from them,” he added.

Their new clues support the idea that double-star systems form when a disk of gas and dust whirling around one young star fragments, forming another new star in orbit with the first. Young stars that still are gathering matter from their surroundings form such disks, along with jet-like outflows rapidly propelling material in narrow beams perpendicular to the disk.

Massive stars form from particularly large disks. It seems likely, at least to me, that large disks are more prone than smaller ones to fragmenting, thus creating massive stars that are born as binaries.

Ann

ESA/Hubble wrote:

After exhausting the nuclear fuel in their cores, stars with a mass of around 0.8 to 8 times the mass of our Sun collapse to form dense and hot white dwarf stars. As this process occurs, the dying star will throw off its outer layers of material, forming an elaborate cloud of gas and dust known as a planetary nebula. This phenomenon is not uncommon, and planetary nebulae are a popular focus for astrophotographers because of their often beautiful and complex shapes. However, a few like Abell 78 are the result of a so-called “born again” star.

Although the core of the star has stopped burning hydrogen and helium, a thermonuclear runaway at its surface ejects material at high speeds. This ejecta shocks and sweeps up the material of the old nebula, producing the filaments and irregular shell around the central star seen in this Picture of the Week, which features data from Hubble’s Wide Field Camera 3 and PANSTARSS.

Rauf wrote: ↑Fri May 31, 2024 2:10 pm

Chris Peterson wrote: ↑Fri May 31, 2024 2:07 pm

Rauf wrote: ↑Fri May 31, 2024 1:59 pm

But why they occur in binary systems? And why their companion is most likely a compact object?

Given that something like 85% of high mass stars are part of binary systems, maybe the question to ask is why only 50% of WR stars are binaries?

OK, so I ask: Why 85% of high mass stars are part of binary systems?

Spaceref.com wrote:

Astronomers know that about half of all Sun-like stars are members of double or multiple-star systems, but have debated over how such systems are formed.

“The only way to resolve the debate is to observe very young stellar systems and catch them in the act of formation,” said John Tobin, of the National Radio Astronomy Observatory (NRAO). “That’s what we’ve done with the stars we observed, and we got valuable new clues from them,” he added.

Their new clues support the idea that double-star systems form when a disk of gas and dust whirling around one young star fragments, forming another new star in orbit with the first. Young stars that still are gathering matter from their surroundings form such disks, along with jet-like outflows rapidly propelling material in narrow beams perpendicular to the disk.

johnnydeep wrote: ↑Fri May 31, 2024 6:36 pm

Chris Peterson wrote: ↑Fri May 31, 2024 6:25 pm

johnnydeep wrote: ↑Fri May 31, 2024 6:14 pm Is the source of the gas in prominent blue arc at the upper left the W-R star? Or is that just gas that happened to be in the vicinity?

It's complicated. W-R stars blow off a lot of material which often generates a local nebula, similar in some ways to a planetary nebula. But they can certainly exist within existing nebulas. I think we're seeing both of those here.

The "fingery" blue ring is clearly from the W-R star, but are you saying that the blue gas arc is likely at least partly gas from the W-R or, that only the ring material is and the arc is just nearby gas? (Though there may be nothing definitive here to prove it one way of the other.)

Chris Peterson wrote: ↑Fri May 31, 2024 6:25 pm

johnnydeep wrote: ↑Fri May 31, 2024 6:14 pm Is the source of the gas in prominent blue arc at the upper left the W-R star? Or is that just gas that happened to be in the vicinity?

It's complicated. W-R stars blow off a lot of material which often generates a local nebula, similar in some ways to a planetary nebula. But they can certainly exist within existing nebulas. I think we're seeing both of those here.

johnnydeep wrote: ↑Fri May 31, 2024 6:14 pm Is the source of the gas in prominent blue arc at the upper left the WR star? Or is that just gas that happened to be in the vicinity?

Ann wrote: ↑Fri May 31, 2024 2:16 pm

Rauf wrote: ↑Fri May 31, 2024 2:10 pm

Chris Peterson wrote: ↑Fri May 31, 2024 2:07 pm

Given that something like 85% of high mass stars are part of binary systems, maybe the question to ask is why only 50% of WR stars are binaries?

OK, so I ask: Why 85% of high mass stars are part of binary systems?

Probably because high-mass stars typically form in clusters, and the very high-mass stars bend spacetime so strongly that other stars of that cluster will fall down into the "gravity well" of the largest star. Sometimes this probably leads to stellar mergers, but much more often the smaller star will simply start orbiting the larger star.

Ann

Rauf wrote: ↑Fri May 31, 2024 2:10 pm

Chris Peterson wrote: ↑Fri May 31, 2024 2:07 pm

Rauf wrote: ↑Fri May 31, 2024 1:59 pm

But why they occur in binary systems? And why their companion is most likely a compact object?

Given that something like 85% of high mass stars are part of binary systems, maybe the question to ask is why only 50% of WR stars are binaries?

OK, so I ask: Why 85% of high mass stars are part of binary systems?

Rauf wrote: ↑Fri May 31, 2024 2:10 pm

Chris Peterson wrote: ↑Fri May 31, 2024 2:07 pm

Rauf wrote: ↑Fri May 31, 2024 1:59 pm

But why they occur in binary systems? And why their companion is most likely a compact object?

Given that something like 85% of high mass stars are part of binary systems, maybe the question to ask is why only 50% of WR stars are binaries?

OK, so I ask: Why 85% of high mass stars are part of binary systems?

Chris Peterson wrote: ↑Fri May 31, 2024 2:07 pm

Rauf wrote: ↑Fri May 31, 2024 1:59 pm

https://astronomy.swin.edu.au/cosmos/W/Wolf-Rayet+Star wrote:It is estimated that about 50% of Wolf-Rayet stars occur in binary systems. Proposed companions are another Wolf-Rayet star, or a compact companion such as a black hole or neutron star. There is some evidence for both of these scenarios, but conclusive observations have yet to be obtained. The only confirmed companions to Wolf-Rayet stars have so far been other massive stars.

But why they occur in binary systems? And why their companion is most likely a compact object?

Given that something like 85% of high mass stars are part of binary systems, maybe the question to ask is why only 50% of WR stars are binaries?

Rauf wrote: ↑Fri May 31, 2024 1:59 pm

https://astronomy.swin.edu.au/cosmos/W/Wolf-Rayet+Star wrote:It is estimated that about 50% of Wolf-Rayet stars occur in binary systems. Proposed companions are another Wolf-Rayet star, or a compact companion such as a black hole or neutron star. There is some evidence for both of these scenarios, but conclusive observations have yet to be obtained. The only confirmed companions to Wolf-Rayet stars have so far been other massive stars.

But why they occur in binary systems? And why their companion is most likely a compact object?

JimB wrote: ↑Fri May 31, 2024 9:03 am

Ann wrote: ↑Fri May 31, 2024 6:34 am a Wolf-Rayet nebula is primarily shaped by the tremendous heat and wind of its own central star
Ann

I have trouble getting my head wrapped round the way that things work on these scales.

If the nebula has something like a 40 light year radius, does that mean that the glow from the nebula has actually been created by radiation that left the star 40 years previously? Or does the nebula glow because it is composed of hot plasma from the star?