Starship Asterisk*

montycash@hotmail.com wrote:
Im brand new.

Just want to know
how yall getting these pictures.

Plz send me info

neufer wrote:For blue supergiants with luminosities a million times the Sun (but masses only 100 times that of the Sun) the radiation pressure exceeds the gravitational attraction by a factor of 10,000 for 1 µm dust grains. A 1 µm dust grain sitting one light year from such a blue supergiant could be pushed out to two light years in about 10,000 years.

neufer wrote:
Dust grains may have icy coatings that "cook" and evaporate in the normal sense of those words.

Dust grain cores are made of refractory materials that only "evaporate" by being blown away due to radiation pressure.

Chris Peterson wrote:

neufer wrote:

Chris Peterson wrote:
The refractory material also evaporates via spallation due to collisions with energetic particles, which is an important source of some elements in dust-rich regions.

• On what sort of time scale

Pretty slow, I imagine. It certainly isn't the dominant component of "evaporation" in these sorts of clouds, not by a long shot. But the process exists. Even hard UV knocks atoms off the surface of refractory dust grains (as opposed to spallation, which creates material with a different atomic number).

MarkBour wrote:I looked around a bit and found some references that said a giant molecular cloud can have up to about 10^6 solar masses of material, but this is dispersed with typical average densities of only about 100 molecules per cm^3. These numbers, though, are not helping my understanding very much, by themselves. I don't think I have any intuitive grasp of them, since I don't have much intuitive grasp of gravity in general.

Ultra-high vacuum chambers, common in chemistry, physics, and engineering, operate below one trillionth (10⁻¹²) of atmospheric pressure (100 nPa), and can reach around 100 particles/cm³.

geckzilla wrote:

MarkBour wrote:The question I'm wondering about, is: "Would passing through this cloud have any significant effect on the orbits of the planets? Could any of them get stripped away, or would there be any other alteration, less drastic, but still significant?"

No. You may as well expect to have your clothes stripped off by the gravitational pull of a passing water cloud here on Earth.

MarkBour wrote:Today's APOD serendipitously illustrates just the kind of encounter I was asking about. We happen to have a star passing through a large cloud. Some basic questions are:

• What is the typical mass density of the cloud forming the Flaming Star nebula? and
• What would that come out to as a total mass?

Now, suppose, hypothetically, that AE Aurigae has a planetary system, much like our own. The question I'm wondering about, is: "Would passing through this cloud have any significant effect on the orbits of the planets? Could any of them get stripped away, or would there be any other alteration, less drastic, but still significant?"

MarkBour wrote: Today's APOD serendipitously illustrates just the kind of encounter I was asking about. We happen to have a star passing through a large cloud. Some basic questions are:

• What is the typical mass density of the cloud forming the Flaming Star nebula? and
• What would that come out to as a total mass?

Now, suppose, hypothetically, that AE Aurigae has a planetary system, much like our own. The question I'm wondering about, is: "Would passing through this cloud have any significant effect on the orbits of the planets? Could any of them get stripped away, or would there be any other alteration, less drastic, but still significant?"

Jim Kaler wrote:

...AE's temperature measured at 36,500 Kelvin (anomalously high for its class; 33,000 might be better). In either case, the star is very luminous, between 26,000 and 33,000 times the luminosity of the Sun (depending on the temperature and the allowance for ultraviolet radiation) and massive (at least 17 times solar...

geckzilla wrote:

MarkBour wrote:
The question I'm wondering about, is: "Would passing through this cloud have any significant effect on the orbits of the planets? Could any of them get stripped away, or would there be any other alteration, less drastic, but still significant?"

No. You may as well expect to have your clothes stripped off by the gravitational pull of a passing water cloud here on Earth.

• Neptunians might notice a change in their auroras.

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

---

<<The heliosphere is the bubble-like region of space dominated by the Sun, which extends far beyond the orbit of Pluto. Plasma "blown" out from the Sun, known as the solar wind, creates and maintains this bubble against the outside pressure of the interstellar medium, the hydrogen and helium gas that permeates the Milky Way Galaxy. The solar wind flows outward from the Sun until encountering the termination shock, where motion slows abruptly. The Voyager spacecraft have actively explored the outer reaches of the heliosphere, passing through the shock and entering the heliosheath, a transitional region which is in turn bounded by the outermost edge of the heliosphere, called the heliopause. The overall shape of the heliosphere is controlled by the interstellar medium through which it is traveling, as well as the Sun, and is not perfectly spherical.>>

MarkBour wrote:The question I'm wondering about, is: "Would passing through this cloud have any significant effect on the orbits of the planets? Could any of them get stripped away, or would there be any other alteration, less drastic, but still significant?"

Chris Peterson wrote: ... Molecular clouds, dust clouds, gas clouds, dark matter- these things don't disrupt planetary systems because they're too diffuse. Disrupting stellar system requires tiny, dense bodies- stars or very large planets.

• What is the typical mass density of the cloud forming the Flaming Star nebula? and
• What would that come out to as a total mass?

neufer wrote:

Chris Peterson wrote:

neufer wrote: Dust grains may have icy coatings that "cook" and evaporate in the normal sense of those words.

Dust grain cores are made of refractory materials that only "evaporate" by being blown away due to radiation pressure.

The refractory material also evaporates via spallation due to collisions with energetic particles, which is an important source of some elements in dust-rich regions.

• On what sort of time scale :?:

(There's a heck of lot of dust in the Universe for it to be as vulnerable to destruction as you suggest.)

Ann wrote:I'm always glad to see a fine RGB image

Ann

Chris Peterson wrote:

neufer wrote:

Ann wrote:
Ordinarily, a hot star like AE Aurigae would "cook" the dust grains in its vicinity to smaller sizes, thereby virtually destroying the chances for a dusty reflection nebula to form. But just because AE Aurigae is a runaway star and just passing through, it hasn't had time to evaporate the dust grains. So the blue tendrils in today's APOD are indeed dusty features,

Dust grains may have icy coatings that "cook" and evaporate in the normal sense of those words.

Dust grain cores are made of refractory materials that only "evaporate" by being blown away due to radiation pressure.

The refractory material also evaporates via spallation due to collisions with energetic particles, which is an important source of some elements in dust-rich regions.

• On what sort of time scale

neufer wrote:

Ann wrote:
Ordinarily, a hot star like AE Aurigae would "cook" the dust grains in its vicinity to smaller sizes, thereby virtually destroying the chances for a dusty reflection nebula to form. But just because AE Aurigae is a runaway star and just passing through, it hasn't had time to evaporate the dust grains. So the blue tendrils in today's APOD are indeed dusty features,

Dust grains may have icy coatings that "cook" and evaporate in the normal sense of those words.

Dust grain cores are made of refractory materials that only "evaporate" by being blown away due to radiation pressure.

Boomer12k wrote:I half expected to see ELVIS...

What a spectacular image!!!
Flaming and firing up the nebula..."Hunka, Hunka Burnin' LOVE...."

:---[===]*

bls0326 wrote:Is there a "bow shock wave" with AE Aurigae? Other articles indicate these speedy stars produce them if there is material in the way. I do not see it, but maybe I am missing it.

Any idea which way the star is moving in this picture (left, right, up, down, in out?)

ManInFla wrote:I think some of the links on the nav bar at the bottom are messed up today...

Ann wrote:
Ordinarily, a hot star like AE Aurigae would "cook" the dust grains in its vicinity to smaller sizes, thereby virtually destroying the chances for a dusty reflection nebula to form. But just because AE Aurigae is a runaway star and just passing through, it hasn't had time to evaporate the dust grains. So the blue tendrils in today's APOD are indeed dusty features,

ManInFla wrote:I think some of the links on the nav bar at the bottom are messed up today...