Messier 16 - The Eagle Nebula / Pillars of Creation in SHO

About the Target

Messier 16, also known as the NGC 6611, and is known by the popular name of “The Eagle Nebula". It has also been called "The Star Queen Nebula" and "The Spire"., but I don’t hear it called that much these days. I would be remiss if I did not mention one of its most famous features, "The Pillars of Creation", which were immortalized by the Hubble Space Telescope. M16 is a large diffuse emission nebula associated with a star cluster located about 5700 light-years away in the constellation of Serpens. This glowing area of dust and gas offers visual dama and glamour which has made it a favorite astrophotography target.

Wikipedia tells us the following about the Pillars of Creation:

"Images produced by Jeff Hester and Paul Scowen using the Hubble Space Telescope in 1995 greatly improved scientific understanding of processes inside the nebula. One of these became famous as the "Pillars of Creation", depicting a large region of star formation. Its small dark pockets are believed to be protostars (Bok globules). The pillar structure resembles that of a much larger instance in the Soul Nebula of Cassiopeia, imaged with the Spitzer Space Telescope in 2005[ equally characterized as "Pillars of Star Creation". or "Pillars of Star Formation". These columns – which resemble stalagmites protruding from the floor of a cavern – are composed of interstellar hydrogen gas and dust, which act as incubators for new stars. Inside the columns and on their surface astronomers have found knots or globules of denser gas, called EGGs ("Evaporating Gaseous Globules"). Stars are being formed inside some of these.

X-ray images from the Chandra observatory compared with Hubble's "Pillars" image have shown that X-ray sources (from young stars) do not coincide with the pillars, but rather randomly dot the nebula. Any protostars in the pillars' EGGs are not yet hot enough to emit X-rays

Evidence from the Spitzer Telescope originally suggested that the pillars in M16 may be threatened by a "past supernova". Hot gas observed by Spitzer in 2007 suggested they were already – likely – being disturbed by a supernova that exploded 8,000 to 9,000 years ago. Due to the distance the main blast of light would have reached Earth for a brief time 1,000 to 2,000 years ago. A more slowly moving, theorized, shock wave would have taken a few thousand years to move through the nebula and would have blown away the delicate pillars. However, in 2014 the pillars were imaged a second time by Hubble, in both visible light and infrared light. The images being 20 years later provided a new, detailed account of the rate of evaporation occurring within the pillars. No supernova is evidenced within them, and it is estimated in some form they still exist – and will appear for at least 100,000 more years."

The Annotated Image

The Location in the Sky

About the Project

Messier 16 has always been one of my Favorite objects in the sky. I think it must have started with those famous Hubble Space Telescope images taken back in 1995.

So when I first started my Astrophotographic journey back in 2019, it was one of the first targets I wanted to shoot. My very first image of it ended up being a pretty crude example - but I could see the "eagle" so I was pretty darn happy with it! Last summer I revisited M16. With a year of Astro imaging under my belt, I felt certain that I could do a dramatically better job than I did with the first. Confidence? No - I just knew that I had set the bar pretty darn low, to begin with. My plan was to capture images over two nights (a first for me at the time) and to process it with Pixinsight - which I was just learning at the time (I don’t think there is an astrophotographer alive that can say that that are not still learning Pixinsight!). I must say that my result was indeed a distinct improvement over my first attempt. Ahhhh - Progress! I was using a One-Shot-Color Camera at the time so reproducing the signature Hubble Palette was just not an option for me - but I was still pretty happy with the image I ended up with. I have not printed many of my Astro images, but I did print that one!

But we come to this year - this was the year that I was really going to nail it! Two full years of Astro imaging and processing under my belt. I had built a computer with 12 cores, gobs of memory, and super-fast SSD drives that could tame Pixinsight with those compute-heavy processes. I also had a telescope platform with a slightly higher focal length and finally, I had a brand new ZWO ASI2600MM-Pro Mono camera setup - a next-generation camera - so for the very first time, I would be able to shoot with Narrowband and use the Hubble Palette! Watch out Hubble - I’m coming to knock you off your perch….

Uncooperative Skies

Then - we entered Rochester's Monsoon Season…… a relatively new feature of the Rochester weather experience

I first set up for this shot back on the Fourth of July and took 2.5 hours of subs before having to shut down by my sky-hogging tree line(I have about a 3-hour window where I can shoot a target before it is eaten by the infernal trees). With some luck, another 3 or 4 more nights should do it and I would have - what I I hoped would be an amazing image.

However, Rochester’s weather gods were not cooperative! I set up my gear on two other nights that looked promising - only to be shut down by incoming clouds before M16 had even cleared my trees. Finally - on Wednesday, July 14th, ClearOutside suggested I had an opening. Gary Opitz - who is a weather wiz, warned me that the smoke plume from the forest fires out west would likely be entering our area - and that would certainly impact my imaging. The Moon was also up but not too bad yet. This would be about my last opportunity to shoot so I had to go for it. The captures seemed to go well but the sky transparency was very bad due to the smoke and because of the high humidity - dew was forming on the scope tubes and running off in streams!

Processing Challenges

When I looked at the data the next day - I knew I would have some challenges. First I had way fewer frames than I had originally planned for. When I scanned what I had with Blink, I found about 25% of the frames had some evidence of very thin clouds passing overhead. These normally would cause me to cull these images before stacking. However, I had so few frames this time - I really did not want to lose any of them if I could avoid it.

The problem was that the impacted images had different gradients depending on when they were taken. This would cause a higher variance for a given pixel when sampled across the subs. It would raise havoc with the rejection algorithms and would cause the final pixel values to be off. I had been hearing about a new script in Pixinsight called “NormalizeScaleGradients” that does something kind of magical. After normal calibration and registration processing, you pick out a reference frame and each sub is then normalized to the gradient seen in this frame. This effectively removes arbitrary differences due to thin clouds, stray lights, and such. Now with all of the subs looking much more similar, the rejection algorithms can work more effectively and the image integration will end up with more data to work with. This suggests that even pretty marginal frames can add some useful data to the final integrated results.

So I kept most of the marginal images in the mix, they had their gradients normalized, and they were integrated into the final master image, weighted by noise measures that modulated their contribution. Anything that lets you keep hard-fought subs into the mix is my friend!

Another problem I had was with star sizes. The star sizes varied a lot for the same star - they varied based on when the sub was taken. So I could expect some ugly stars. Narrowband images often produce funky stars and I typically shoot RGB stars and replace the Narrowband stars with something that looked more natural. But given the limited access, I had to the target, I was not able to capture any RGB frames to enable that.

So I need up spending a lot of time with image processing. About two and half days. Each step I played with it, trying many variations until I found what I thought worked best for each step

I was very careful to maximize what I could get with deconvolution. I was also able to shrink some of the star sizes further using a deconvolution trick I learned from an Adam Block video. Basically, you take the point spread function model image created by PFSImage and trim the outer edges a bit before using it in deconvolution. This did help shrink the stars - but I still had mismatches between the filter channels so I spent a lot of time with star masks trying to help things out. And I did help things a bit - they were much better than when I started, but having said that - don't look too carefully at the stars in this image as they are a mess!

Previous Efforts

Link to the Second Effort Posting

More Information

Wikipedia Entry: Messier 16

NASA: Hubble Space Telescope image of “The Pillars of Creation”

Capture Details

Lights Frames

• Taken the nights of 7/4/21 & 7/14/21

• 18 x 300 seconds, bin 1x1 @ -15C, Gain 100.0, Astronmiks 6nm Ha Filter

• 14 x 300 seconds, bin 1x1 @ -15C, Gain 100.0, Astronmiks 6nm OIII Filter

• 15 x 300 seconds, bin 1x1 @ -15C, Gain 100.0, Astronmiks 6nm SII Filter

• Total of 3.9 hours

Cal Frames

• 30 Darks at 300 seconds, bin 1x1, -15C, gain 100

• 25 Dark Flats at Flat exposure times, bin 1x1, -15C, gain 100

• Flats done separately for each evening to account for camera rotator variances:

  • 25 Ha Flats

  • 25 OIII Flats

  • 25 SII Flats

Capture Hardware