Starship Asterisk*

VictorBorun wrote: ↑Fri Jan 08, 2021 6:25 pm
ok, then a galactic bar is such a stick-shaped region of dense stellar population that happens to stand still in a rotating reference system.

Ann wrote: ↑Mon Jan 04, 2021 4:10 am

NGC 1300, a barred galaxy with an inner ring. The inner ring is not bright, however, and contains little or no star formation. The galaxy displays an increased amount of star formation particularly at the 'right' end of the bar. Photo: NASA, ESA, and The Hubble Heritage Team STScI/AURA).

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The bar structure is not solid, but it is dense as stellar structures go. That is to say, it contains a very large number of stars.

Also remember that almost all bars are yellow. Galactic features that are bright and yellow always contain a very high number of stars. That is because the individual stars that make up bright yellow features in galaxies are not bright themselves, and in fact, most of them are fainter - or indeed, a lot fainter - than the Sun. That is because there is almost never star formation in the bar, and the vast majority of long-lived stars are little red dwarfs.

So in order to be as bright as bars often are, they have to be very full of small stars and therefore really massive. Through density waves, the bars rotate as solid bodies, even though they are not solid. As they rotate, they sweep up gas and channel it into two places: At the ends of the bar, which often see increased star formation, and into a small central ring surrounding the nucleus.

Ann

VictorBorun wrote: ↑Fri Jan 08, 2021 12:00 am But the bar is a stick rotating in galactic disk plane, isn't it?

VictorBorun wrote: ↑Thu Jan 07, 2021 7:25 pm Come to think of it, if we have a rotating globular cloud of constant density, its equatorial plane cross-section must be moving like a solid body.
There can be strings or bars that don't get smeared by the difference in orbiting periods.
Sadly real globular clouds are not dense enough and self-gravitating enough to rotate fast and manage to do multiple round-abouts. No chance to see bars inside globular gas clouds.

neufer wrote: ↑Thu Jan 07, 2021 2:27 pm

Rotation curve of spiral galaxy Messier 33 (yellow and blue points with error bars), and a predicted one from distribution of the visible matter (gray line). The discrepancy between the two curves can be accounted for by adding a dark matter halo surrounding the galaxy.

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Beyond the central black hole, the first ~20% of most disc galaxies shows a quasi-linear velocity rotation curve indicative of a (harmonic) constant rotation period T due to a constant density (mostly light) spherical matter halo.

Now... whether the bars themselves are semi-permanent objects that rotate at this very same period T remains to be seen...but it seems like a not unreasonable assumption.

Ann wrote: ↑Mon Jan 04, 2021 4:10 am

NGC 1512, a barred galaxy with an outer and an inner ring. The outer ring displays an increased amount of star formation on its 'left' side. The inner ring is quite bright and contains many young blue stars. Photo: NASA, ESA, Hubble Space Telescope.

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Through density waves, the bars rotate as solid bodies, even though they are not solid. As they rotate, they sweep up gas and channel it into two places: At the ends of the bar, which often see increased star formation, and into a small central ring surrounding the nucleus.

VictorBorun wrote: ↑Thu Jan 07, 2021 5:33 am
So the bar does not propagate through a media, it rotates as a heavy and solid body.

To stay stick-like, it must have one and the same rotation period T, and so acceleration toward the center must be (4π²/T²)R ~ R, and so there must be constant density dark matter halo to account for gravity ~R. Or not?

VictorBorun wrote: ↑Thu Jan 07, 2021 5:33 am
So the bar does not propagate through a media, it rotates as a heavy and solid body.
To stay stick-like, it must have one and the same rotation period T, and so acceleration toward the center must be (4π²/T²)R ~ R, and so there must be constant density dark matter halo to account for gravity ~R. Or not?

Ann wrote: ↑Mon Jan 04, 2021 4:10 am

NGC 1512, a barred galaxy with an outer and an inner ring. The outer ring displays an increased amount of star formation on its 'left' side. The inner ring is quite bright and contains many young blue stars. Photo: NASA, ESA, Hubble Space Telescope.

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Through density waves, the bars rotate as solid bodies, even though they are not solid. As they rotate, they sweep up gas and channel it into two places: At the ends of the bar, which often see increased star formation, and into a small central ring surrounding the nucleus.
Ann

VictorBorun wrote: ↑Mon Jan 04, 2021 3:11 am

Ann wrote: ↑Sun Jan 03, 2021 5:55 am Check out this video, which shows the formation of a spiral galaxy. Note how the galaxy gradually evolves a bar.
Ann

Video is great, thanks.
But now I don't understand how come that the core, though low-gas and populated mostly with long-living stars, is solid enough to cunduct a density wave.
A galaxy arm, with many shining blue nebules, is one thing. Blue supergiants manage to form and discharge while an arm is propagating across the media.

But the core? The bar? Are there this many stars forming and discharging as the bar's ends move across the disk?

Ann wrote: ↑Sun Jan 03, 2021 5:55 am Check out this video, which shows the formation of a spiral galaxy. Note how the galaxy gradually evolves a bar.
Ann

VictorBorun wrote: ↑Sun Jan 03, 2021 1:37 am
I wonder if LMC is an ordinary flat gas/dust disk spiral galaxy with a bar at its core.

What is a bar in a barred galaxy anyway?
Is it a binary system of cores in the moment of merge?
Is it a disk with another plane that we get to see edge-on?

Wikipedia wrote:

Magellanic spiral galaxies are (usually) dwarf galaxies which are classified as the type Sm (and SAm, SBm, SABm). They are galaxies with one single spiral arm, and are named after their prototype, the Large Magellanic Cloud, an SBm galaxy. They can be considered to be intermediate between dwarf spiral galaxies and irregular galaxies.

Wikipedia wrote:
A barred spiral galaxy is a spiral galaxy with a central bar-shaped structure composed of stars.
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The creation of the bar is generally thought to be the result of a density wave radiating from the center of the galaxy whose effects reshape the orbits of the inner stars. This effect builds over time to stars orbiting further out, which creates a self-perpetuating bar structure.
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Recent studies have confirmed the idea that bars are a sign of galaxies reaching full maturity as the "formative years" end. A 2008 investigation found that only 20 percent of the spiral galaxies in the distant past possessed bars, compared with about 65 percent of their local counterparts.

Ann wrote: ↑Fri Jan 01, 2021 12:23 pm

Sigma Octantis

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Ann

Ann wrote: ↑Fri Jan 01, 2021 9:10 am And finally, Sigma Octantis shines bright in today's APOD! (Well, 40 times brighter than the Sun, though from a distance of 280 light-years.) At right it can be found in the brilliant APOD from June 28, 2018, by Frank Sackenheim, but I can't possibly find it in today's APOD. Does anyone else have any luck?

https://en.wikipedia.org/wiki/Sigma_Octantis wrote:

Sigma Octantis is the dimmest star to be represented on a national flag. It appears on the flag of Brazil, symbolising the Brazilian Federal District.

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<<Sigma Octantis (also written as σ Octantis; abbreviated as Sig Oct), officially named Polaris Australis, is the current South Star. This is a solitary star in the southern circumpolar constellation of Octans.

Located approximately 281 light-years from Earth, it is classified as a giant star with a spectral type of F0 III. Sigma Octantis is a 1.59 M_☉ Delta Scuti variable, with its average magnitude of 5.47 varying by about 0.03 magnitudes every 2.33 hours.

[Polaris Aa is a 5.4 M_☉ F7 yellow supergiant low-amplitude Population I classical Cepheid variable varying in magnitude 1.86–2.13 every 4 days or so.]

Sigma Octantis is barely visible to the naked eye, making it unusable for navigation. Because of this, the constellation Crux is often preferred for determining the position of the South Celestial Pole.>>

https://en.wikipedia.org/wiki/Delta_Scuti_variable wrote:
<<A Delta Scuti variable (sometimes termed dwarf cepheid when the V-band amplitude is larger than 0.3 mag.) is a subclass of young pulsating star. These variables as well as classical cepheids are important standard candles and have been used to establish the distance to the Large Magellanic Cloud, globular clusters, open clusters, and the Galactic Center. SX Phoenicis variables are generally considered to be a subclass of Delta Scuti variables that contain old stars, and can be found in globular clusters.

The OGLE and MACHO surveys have detected nearly 3000 Delta Scuti variables in the Large Magellanic Cloud. Typical brightness fluctuations are from 0.003 to 0.9 magnitudes in V over a period of a few hours, although the amplitude and period of the fluctuations can vary greatly. The stars are usually A0 to F5 type giant or main sequence stars.

Delta Scuti stars exhibit both radial and non-radial luminosity pulsations. The stars have a helium rich atmosphere. As helium is heated it becomes more ionised, which is more opaque. So at the dimmest part in the cycle the star has highly ionised opaque helium in its atmosphere blocking part of the light from escaping. The energy from this “blocked light” causes the helium to heat up, expand, ionise, become more transparent and therefore allow more light through. As more light is let through the star appears brighter and, with the expansion, the helium begins to cool down. Hence the helium contracts and heats up again and the cyclical process continues. Throughout their lifetime Delta Scuti stars exhibit pulsation when they are situated on the classical Cepheid instability strip. They then move across from the main sequence into the giant branch.

The prototype of these sorts of variable stars is Delta Scuti (δ Sct), which exhibits brightness fluctuations from +4.60 to +4.79 in apparent magnitude with a period of 4.65 hours. Other well known Delta Scuti variables include Altair, Denebola (β Leonis) and β Cassiopeiae. Vega (α Lyrae) is a suspected Delta Scuti variable, but this remains unconfirmed.>>