Starship Asterisk*

neufer wrote: ↑Wed Jun 05, 2019 10:42 pm

AVAO wrote: ↑Wed Jun 05, 2019 9:40 pm
What is unclear to me is that the Barnard's Loop should be a SNR, but only half a circle is visible and when you look into the center, there is nothing unusual to discover...

• Elvis has left the building:

https://en.wikipedia.org/wiki/Stellar_kinematics#Runaway_stars wrote:
<<A supernova explosion in a multiple star system can accelerate
both the supernova remnant and/or remaining stars to high velocities.

An example of a related set of runaway stars is the case of AE Aurigae, 53 Arietis and Mu Columbae, all of which are moving away from each other at velocities of over 100 km/s (for comparison, the Sun moves through the Milky Way at about 20 km/s faster than the local average). Tracing their motions back, their paths intersect near to the Orion Nebula about 2 million years ago. Barnard's Loop is believed to be the remnant of the supernova that launched the other stars.>>

rstevenson wrote: ↑Thu Jun 06, 2019 5:05 pm
That's a nice list, Art. What is it a list of?

Elements, yes -- presumably elements created inside a star.

But a particular star? The progenitor star of this particular SNR?

https://en.wikipedia.org/wiki/Abundance_of_the_chemical_elements wrote:
The table shows the most abundant nuclides [currently] in the Solar System in parts per million (ppm).

The abundance of elements in the Sun and outer planets is similar to that in the [nearby] universe.

Chris Peterson wrote: ↑Thu Jun 06, 2019 1:05 pm

Boomer12k wrote: ↑Thu Jun 06, 2019 1:45 am
There SEEMS to be a LOT of Sulfur....

It's a bit dangerous to draw that conclusion from an image like this, where each channel represents a different exposure time, and the processing workflow scales those channels differently, and may even mix data between channels. This image is better at showing what elements are where than it is at showing absolute amounts. For that, you'd want to go back to the raw data and analyze it photometrically. You can't do that with the processed image.

Nuclide 	A 	Mass ppm 	Atom ppm
----------------------------------------------------
Hydrogen-1 	1 	705,700 	909,964
------------------------------------------------
Helium-4 	4 	275,200 	88,714
------------------------------------------------
Oxygen-16 	16 	9,592 		477
Carbon-12 	12 	3,032 		326
Nitrogen-14 	14 	1,105 		102
Neon-20 	20 	1,548 		100
------------------------------------------------
Silicon-28 	28 	653 		30
Magnesium-24 	24 	513 		28
Iron-56 	56 	1,169 		27
Sulfur-32 	32 	396 		16
Helium-3 	3 	35 		15
Hydrogen-2 	2 	23 		15
Neon-22 	22 	208 		12
------------------------------------------------
Magnesium-26 	26 	79 		4
Carbon-13 	13 	37 		4
Magnesium-25 	25 	69 		4
Aluminium-27 	27 	58 		3
Argon-36 	36 	77 		3
Calcium-40 	40 	60 		2
Sodium-23 	23 	33 		2
Iron-54 	54 	72 		2
Silicon-29 	29 	34 		2
Nickel-58 	58 	49 		1
Silicon-30 	30 	23 		1
Iron-57 	57 	28 		1 

Boomer12k wrote: ↑Thu Jun 06, 2019 1:45 am The big picture...after clicking on the image...magnified, is awesome...

There SEEMS to be a LOT of Sulfur....

Boomer12k wrote: ↑Thu Jun 06, 2019 1:45 am There SEEMS to be a LOT of Sulfur....
:---[===] *

³²S is created inside massive stars, at a depth where the temperature exceeds 2.5×10⁹ K, by the fusion of one nucleus of silicon plus one nucleus of helium.[18] As this nuclear reaction is part of the alpha process that produces elements in abundance, sulfur is the 10th most common element in the universe.

AVAO wrote: ↑Wed Jun 05, 2019 9:40 pm
What is unclear to me is that the Barnard's Loop should be a SNR, but only half a circle is visible and when you look into the center, there is nothing unusual to discover...

• Elvis has left the building:

https://en.wikipedia.org/wiki/Stellar_kinematics#Runaway_stars wrote:
<<A supernova explosion in a multiple star system can accelerate
both the supernova remnant and/or remaining stars to high velocities.

An example of a related set of runaway stars is the case of AE Aurigae, 53 Arietis and Mu Columbae, all of which are moving away from each other at velocities of over 100 km/s (for comparison, the Sun moves through the Milky Way at about 20 km/s faster than the local average). Tracing their motions back, their paths intersect near to the Orion Nebula about 2 million years ago. Barnard's Loop is believed to be the remnant of the supernova that launched the other stars.>>

pferkul wrote: ↑Wed Jun 05, 2019 3:32 pm Very impressive image! I was wondering if the dark blobs in the lower left corner are real or image processing artifacts? See attached enhanced image. Also similar appearance in upper left corner.