Thursday, June 22, 2023

3rd Object from "Supernova Week" - M27

Messier 27 - The Dumbbell Nebula

The week of 05/21/2023 was a fantastic week for imaging. Not only did I capture multiple nights SN 2023ixf in M101 (click here) and The Iris Nebula (click here), I was also able to capture two other targets. On the night of 05/24/2023 (actually the morning of 05/25/2023) I imaged Messier 27, The Dumbbell Nebula after losing M101 to a tree somewhere around 1:30 AM. Sky conditions were very good, so I slewed to M27 and imaged until the end of Astronomical Dark (2:04 AM to 3:35 AM). 


An image of M27 captured on 05/25/2023. This target is quite small for my imaging setup, so the image is cropped in significantly. 

I'm pretty happy with the way this turned out. After watching RC-Astro's Russ Croman on The Astro Imaging Channel (TAIC), I used his MTF Analyzer to analyze my setup. According to the tool, I'm slightly under-sampled and would benefit from using 2X drizzle integration. I tried it and I think it was worthwhile. M27 is a very small target for my set up (480 mm refractor with APS-C sensor). Therefore, the image presented here has been cropped in significantly. 

What is it?

Messier 27 is a planetary located in the constellation Vulpecula. M27 is the first Planetary Nebula ever discovered. A Planetary Nebula is an emission nebula formed from an expanding shell of ionized gas ejected by stars (like our Sun) too small to go supernova when they (stars) are late in their lives. A stellar remnant known as a White Dwarf is left behind and is responsible for ionizing the gas. M27 is a popular target for amateur astronomers as it is visible in binoculars and telescopes. 

How big is it?

It has an angular size of 8 x5.7 arcminutes on the night sky and has a diameter of about 3.2 light-years. 

How far is it?

The M27 is within the Milky Way at about 430 parsecs (pc) or 1,400 light-years (ly) from Earth.

How to find it?

M27 is a popular target for visual astronomers. A nebula filter (like a UHC or OIII filter) can really help make it pop visually. M27 is located within the Summer Triangle. 

Refer to the finder chart below. 

  1. Find the Summer Triangle (Vega, Deneb, & Altair).
  2. Locate the star Albireo (the head of Cygnus the Swan).
  3. Rough location method:
    1. Using the finder Chart below, M27 is one vertex of an imaginary triangle with the other vertices Altair & Albireo. 
  4. If you have dark enough skies to see the constellations Sagitta (actually looks like an arrow) and Vulpecula, you can use the finder chart below to refine the position of M27.

Finder chart for M27.

Image Details:

Capture Date:05/24/2023
Location: Eden, NY
Telescope: Explore Scientific ED80 Essential Series Air-Spaced Triplet Refractor
Camera: ZWO ASI2600MC Pro
Filter: None
Mount: Sky-Watcher USA EQ6-R Pro
Exposure: 60 exposures at 60 sec / Gain 100 / Offset 50 / -10°C each for a total exposure of 1 hour.
Software: NINA, SharpCap Pro, PHD2, and PixInsight


Clear Skies!
Ernie

Sunday, June 11, 2023

Reflection in the Dark - The Iris Nebula

 It was a really good week for astrophotography!

Starting on the night of Sunday May 21st through Friday May 26, we had a great stretch of weather for astrophotography, at least as far as Western New York is concerned. Sunday and Monday were impacted by smoke from the wildfires in Alberta, Canada. Even with the smoke, I managed to capture data on SN 2023ixf in M101 (click here). Wednesday, Thursday, & Friday had better conditions. Being able to leave my scope setup all the way through Saturday (extremely rare for our area).

On Wednesday night I started the evening on SN2023ixf in M101 and then moved to another target (post coming soon) as I lose M101 in a tree around 1:30 AM. Not wanting to squander the clear skies I added a sequence for second target to NINA. Technically this was the morning of Thursday May 25th since it was after midnight. However, that's not how I think about it and organize my files. I started the imaging session on the night of Wednesday May 24th and carried that date through sunrise. That's the convention I follow, right or wrong. 

On Thursday, the Moon was setting around 1:30 AM. Thought I would try for the Iris Nebula. This target is something I've wanted to image for a while, but avoided as I considered it more of an "advanced" target. As my skills have been progressing, thanks to experience, mentors in the BAA, and knowledge/skill gained form Masters of PixInsight classes, I decided to give it a shot. glad I took the chance. On Friday I did not image M101, just felt like trying something different. I didn't want to go to the Iris right way because the Moon was brighter and wasn't going to set until 1:52 AM. So imaged another target (post coming soon) until 1:30 am and then switched back to the Iris. I think Thursday night was the best night of the week. 

The image was processed in PixInsight. It took multiple attempts to get this result, but I'm really pleased with it. Still a little unsure (due to inexperience with dust and dark nebulae surrounding the reflection nebula) I posted it on Twitter and asked for feedback. The feedback was very positive. I also shared the image with members of the imaging group within the BAA. Again, the feedback was positive. 

For the first time since I started imaging with this Deep sky setup, the hard drive on my imaging laptop was nearly full by the end of the week. Will need to consider upgrading the storage on the laptop. This was an unusual problem to have as we almost never get that many good nights so close together. It was a really fun week chasing the supernova in m101 and imaging the Iris and the other targets I went after. Very reminiscent of chasing Comet Neowise in 2020. I hope you enjoy the image.


The Iris Nebula (NGC 7023 / LBN 487) captured on 05/25/2023 & 05/26/23.

What is it?

The Iris Nebula is a fairly bright reflection nebula in the constellation of Cepheus. The reflection nebula is surrounded by lots of dust. The Iris Nebula is also known as NGC 7023, Caldwell 4, and LBN 487. Unlike emission nebulae, reflection nebulae do not emit their own light. The color comes from scattered light of its central star. Reflection nebulae are made up of very small particles, much smaller than dust particles on Earth. these particles scatter light giving the nebula its bluish color (similar to our sky).

An annotated image of the Iris Nebula and surrounding dust. 


How big is it?

It has an angular size of 18 x 18 arcminutes on the night sky and is about 6 light-years across. 

How far is it?

The Iris Nebula is within the Milky Way at about 420 parsecs (pc) or 1,400 light-years (ly) from Earth.

How to find it?

This object can be observed visually as well as being a popular photographic target. Dark skies are a must. 

Refer to the finder chart below. 

  1. Find Cassiopeia with its distinctive "M" or "W" shape.
  2. Find Polaris (the North Star).
  3. Find Cygnus or the Northern Cross. 
  4. The constellation Cepheus looks like a house and is located between items 1,2, & 3.
  5. The Iris Nebula is within the red box on the finder chart (the red box indicates the field of view of the image.
 

A finder chart for the Iris Nebula.

Image Details:

Capture Date:05/25/2023 and 05/26/2023
Location: Eden, NY
Telescope: Explore Scientific ED80 Essential Series Air-Spaced Triplet Refractor
Camera: ZWO ASI2600MC Pro
Filter: None
Mount: Sky-Watcher USA EQ6-R Pro
Exposure: 5/25/: 60 exposures at 120 sec each; 5/26: 50 exposures at 120 sec each for a total exposure of 3.67 hours. Gain 100 / Offset 50 / -10°C for both nights.
Software: NINA, SharpCap Pro, PHD2, and PixInsight

Clear Skies!
Ernie





Monday, June 5, 2023

Chasin' SN 2023ixf in M 101

A star went BOOM!


About 21 million years ago in the galaxy Messier 101, the Pinwheel Galaxy, a star went boom. It really went boom. Specifically, a Core Collapse Supernova known as a Type II Supernova, one of the most energetic events in the Universe. This particular supernova was first observed on May 19, 2023, by Koichi Itagaki. The Zwicky Transient Facility confirmed the discovery and found an image of the supernova (much fainter) from two days before the discovery observation. 


A recent image of M 101 from before the supernova. 


Type II Supernova Facts


  • This type of supernova occurs for stars at least 8 times more massive than our Sun and will leave behind a Neutron Star or Black Hole. 
  • Supernovae can outshine their host galaxies, releasing as much energy in a single burst as our Sun will release in 10 billion years. 
  • Many of the elements heavier than iron are created in this type of Supernovae.
  • Supernovae produce a mind bogglingly large number of Neutrinos. In 10 seconds a core-collapse supernova will release 1058 neutrinos.
  • Supernovae can accelerate particle to at least 1000 times the energy of particles in the Large Hadron Collider. 

Good Timing


The timing of this event was favorable for observation by amateur astronomers in the northern hemisphere due to the following factors:
  • M 101 is located just off the handle of the Big Dipper in the constellation Ursa Major. 
  • M 101 is a popular target for amateur astronomers, especially in the northern Hemisphere's spring, known to amateur astronomers as galaxy season. 
  • M101 is high in the sky, making it favorable for observation. 
  • Astronomically speaking, 21 million light years is "close" and therefore SN 2023ixf appears bright.
This event is for those of us located in the northern hemisphere, as M 101 is near the North Celestial Pole. Unfortunate news for our friends in the southern hemisphere. I don't feel too bad for them, as they have had their fair share of amazing events and amazing objects not accessible to those of us in the north.

A finder chart for finding M 101.

My Observations:


Night 1 - Sunday May 21, 2023:


My first shot at SN 2023ixf was Sunday May 21st. The forecast was calling for clear skies. Unfortunately, the forecast was also calling for dense smoke because of the wildfires in Alberta, Canada. I set up well before dark and hoped for the best. As it got dark, the stars were slow to appear. I could make out the crescent Moon near the horizon in the west and Venus was visible a little higher in the western sky. About 10 minutes before 10 pm, I could see Arcturus followed by a few stars in the Big Dipper. The smoke was definitely impacting the visibility of the stars. I decided to connect to my guide camera and see polar alignment was possible, and it was successful. Followed this up by slewing the telescope to the south, to an object close to where the Meridian and Celestial Equator (Dec = 0) for PHD2 guiding calibration. Again, this was successful. With both tasks successful completed, it was time to go for the supernova. I recently imaged M 101 at the end of April (click here). One of my sub exposures from that session was used to frame the target, this would capture the object in the same orientation, facilitating before and after comparisons. After slewing to M 101, rotating the camera to match the previous image, and performing an autofocus run, NINA started capturing the first image. SN 2023ixf was clearly visible in the resulting image, even though the galaxy details were subdued by the smoke. NINA continued to capture exposures, and SharpCap live stacked them. I don't have the writing skills to properly convey how exciting this was. 

Prior to starting the image session, I connected to an impromptu Zoom meeting with members of our local astronomy club, the Buffalo Astronomical Association (BAA). I was joined by our Observatory Director and a member from a sister club in Rochester, NY (who also belongs to our club). This person maintains a very useful website on supernovae (click here). It's a fantastic resource and I've used it for years before meeting him in person at our last club picnic. 

A total of 26 Images were captured from 10:07 PM to 11:17 PM, when the conditions degraded, and it no longer made sense to continue. Exposures were 120 sec each at a Gain of 100 with an Offset of 50. The images were captured on my Home Setup:

  • Telescope: Explore Scientific Essential Series ED80 Air Spaced Triplet
  • Mount: Sky-Watcher EQ6-R Pro
  • Camera: ZWO ASI2600MC Pro
  • Filter: None
  • Accessories: Pegasus Astro Pocket Power Box Advanced, ZWO EAF, ZWO ASI224MC, Explore Scientific Field Flattener, & Orion 50 mm Mini Guide Scope 
  • Software: NINA, PHD2, SharpCap, & PixInsight

Single 120 sec exposure. A screenshot from the capture software NINA. Only a screen (display) stretch applied, no other processing. Look how bright the supernova is compared to the galaxy. 

The live stacked image from SharpCap. This is a a total of 26 exposures at 120 sec each for a total exposure of 52 minutes. The image was saved with the display stretch and the plug-in NoiseXTerminaror was applied in PixInsight to reduce the noise in the image.

The final processed image. A total of 22 exposures were used (the last 4 images captured were too severely degraded to use). The image was processed in PixInsight. 

Night 2 - Monday May 22, 2023: 


The forecast was calling for clear skies and dense smoke. I headed out to the Buffalo Astronomical Association's observatory (Beaver Meadow Observatory) for our weekly imaging group session. The group is called the Tuesday Night Imagers, but "Tuesday" can be pretty much any day of the week. This week it was Monday. I set up my ZWO ASI2600MC Pro on the club's Tele Vue NP-101is and another member setup his ZWO ASI1600MM Pro on the club's Celestron 14" Edge HD Telescope. Both scopes sit atop an Astro Physics AP1200 mount in our main observatory. The club's Observatory Director is the leader of the Tuesday Night group. He was traveling, so another member and I were running the session in his place. We made a couple of critical errors which will make getting anything off of the 14'" scope a challenge. The first issue is the OAG prism wasn't properly lined up with the imaging camera's sensor. This resulted in a prominent shadow in the corner of the exposures. Compounding this error, we took flats at Bin 1, which does not match our light frames taken at Bin 2. There may be a way to salvage the data, but that will have to wait for another day. 

In addition to running the Tuesday Night session in place of the group's leader, we had an unusually large turnout due to the excitement of the supernova. Unfortunately, the smoke was very dense. most left around 10:30 PM. The supernova was visible in exposures but hardly any detail of the galaxy. Two of us stayed behind to troubleshoot the shadow issue on the 14". We continued to take exposures. We experienced a brief window where the smoke was not so dense. We captured images in both scopes for about a half an hour. After which we shut everything down and went home. 



BAA members setting up outside the observatory to observe/image the Supernova.

The Moon and Venus

Another view of the Moon and Venus

The Moon and Venus over our (the BAA) newly acquired Sky shed Pod.

A photo of the screen showing a single 120 sec exposure of from the NP-101is when the smoke briefly cleared.  BAA Tuesday Night Imagers.

A photo of the screen showing a 120 sec exposure from the 14" Edge HD.
BAA Tuesday Night Imagers.


Processed image captured on the NP-101is. Image was processed in PixInsight. BAA Tuesday Night Imagers.



Night 3 - Wednesday May 24, 2023


Conditions were much better on Wednesday May 24th. My scope (Home Setup) was still setup from Monday Night. I imaged from dark until about 1:30 AM, when I lost this object to a tree. Unfortunately, after processing the image, I accidentally deleted the raw data while moving files to a backup hard drive, as the hard drive on my imaging computer was getting full. Needless to say, I'm not pleased with myself about this mistake! This image was made from a total of 85 exposures at 120 seconds / Gain 100 / Offset 50 each for a total exposure of 2.8 hours. Processing was done in PixInsight. 





Night 4 - Thursday May 25, 2023


Conditions were very good again on Thursday May 25, 2023. Another image from my home setup. I imaged from 9:52 PM until 1:27 AM. Conditions were good enough that I continued to image another target (while I slept) after losing M 101. That will be covered in a future post. As the Moon was getting brighter and setting later, I decided to back off on my exposure time from 120 seconds to 60 sec. This image was made from a total of 145 exposures at 60 sec / Gain 100 / Offset 50 for a total exposure of 2.4 hours.



Putting all together in a Movie/Animation

Starting with my image of M101 from 4/26 (before the Supernova), I Star Aligned the processed images from each night using PixInsight. Then cropped them with Dynamic Crop in PixInsight. Photoshop was used to add the markers, the text, and to create the animation. Each frame has a 2 second duration. I converted the animation from a GIF to a MP4 movie file. Hope you like the result.


So, What's Next?

SN 2023ixf will be visible for a few more weeks. It will slowly dim.  Will probably try and capture some more data if time and weather allow. Our Observatory Director and the person from the Rochester club that maintains the supernova website both provided me with information on how to determine the magnitude of the Supernova from my images. I intend to sit down and learn how to do this. When, not sure. When I do figure it out, I'll make another post or amend this one. 

Clear Skies!
Ernie








Wednesday, May 3, 2023

M101 - The Pinwheel Galaxy

 

M101 - The Pinwheel Galaxy - captured on 04/26/2023

What is it?

M101 is a very large, face-on spiral Galaxy also known as The Pinwheel located in the constellation Ursa Major. It is a Grand Design Spiral Galaxy. It's asymmetric shape and very well defined spiral arms are likely the result of gravitational interactions with neighboring galaxies. It also has high levels of star formation, also likely caused by the same gravitational interactions. 

How big is it?

It has an angular size of 24 x 23 arcminutes on the night sky. It's about 170,000 light-years across (almost twice the size of our Milky Way Galaxy). It has about a trillion a contains the mass of about 100 billion solar masses.

How far is it?

M1010 is 7.1 Mega Parsecs (Mpc) or 23 million light-years (Mly) from Earth.

How to find it?

Even though M101 is fairly bright at magnitude 7.9. Unfortunately, due to its large angular size, it has a low surface brightness. Larger aperture and dark skies will help in finding and observing this object. 

Refer to the finder chart below. 

  1. Find the Big Dipper
  2. Find the star at the end of the handle (Alkaid)
  3. Find the second star in the handle of the big dipper, Mizar, where the handle bends. Mizar is not labeled in the finder below. Side Note: See if you can see Mizar's fainter companion, Alcor. Alcor and Mizar are naked eye double star. 
  4. Referring to the finder chart, draw an imaginary isosceles triangle with Alkaid and Mizar as the first two vertices of the triangle. M101 is the third vertex.


Finder chart for M101

Image Details:

Capture Date: 04/26/2023
Location: Eden, NY
Telescope: Explore Scientific ED80 Essential Series Air-Spaced Triplet Refractor
Camera: ZWO ASI2600MC Pro
Mount: Sky-Watcher USA EQ6-R Pro
Exposure: 124 exposures at 120 sec each / Gain 100 / Offset 50 / -10°C  for a total exposure of 4.13 hours
Software: NINA, SharpCap Pro, PHD2, and PixInsight


Saturday, April 29, 2023

Imaging a Favorite Visual Target (M44 - Beehive Cluster)

Working on the New Camera


Sunday night April 9th (2023) was a clear night. Clear nights have been far and few between this year. Took the opportunity to work on optimizing the setup for my camera. In January of this year, I purchased my first Dedicated Astronomy Camera, the ZWO ASI2600MC Pro. Quite the step up from my DSLR. In the few opportunities that I've had to use the camera, confirmed that I have sensor tilt (the sensor is not square to the optical path). Spent the first night working on that, with some success (took the tilt from Severe to mild). The skies were amazing and I stopped making adjustments. Will need to make a few more subtle tweaks next clear night, didn't want to waste any more imaging time. Since it was a work night, was looking for a target that didn't require many hours of integration. Aha! M44, The Beehive Cluster. This checked a few boxes like: didn't require many hours of exposure, would be a good target to evaluate impact of adjustment as it's all stars, was well placed in the sky, and I love looking at this cluster through binoculars. Star Clusters aren't necessarily the "sexiest" choice of targets compared to Nebulae and Galaxies, but I have a soft spot for them, so this won't be the last cluster I image.

Messier 44 (M44) also known as The Beehive


What is it?

Messier 44, also known as The Beehive or Praesepe, is an open star cluster located in the constellation of Cancer. Unlike many of the Nebulae and Galaxies we image, open star clusters are great visual targets. M44 is even Naked Eye visible from dark skies, appearing as fuzzy star. Optical Aid, preferably binoculars or a wide field refractor (in my opinion) will reveal the individual stars. binoculars will reveal about 75 stars with larger telescopes revealing more. The cluster contains about 100 members, most of which are M dwarfs. The mass of the cluster is about 500 times the mass of our Sun. The best time to view this cluster for northern latitude observers is from February through May.

How big is it?

M44 is about 95' (arcminutes) in diameter. The cluster is 16 light-years across.

How old is it?

The cluster is about 600 -700 million years old.

How far is it?

577 light-years or 177 parsecs from Earth.

How to find it?

When we observe many of the objects that we typically image with our visual observing equipment, we typically don't see the same color and details. This does not make visual observing less valid or impactful, just a different experience. However, star clusters are an (generally speaking) exception. They will also punch throw light pollution, of course the view is always better in dark skies. Star clusters like M44 are often excellent objects to observe in binoculars and telescopes with a wider field of view due to their angular size in the night sky. for perspective, M44 is 95' across and the Full moon is only about 30'. These factors combine to make star clusters an excellent choice for visual observation for a wide range of astronomers and their respective equipment. Personally, this is one of my favorite springtime targets to visually observe.

Finding M44 is pretty easy even though the constellation of Gemini is a very dim constellation. Refer to the finder chart below and follow these steps:

  1. Find the bright star Pollux in the constellation of Gemini, in the West-Southwest sky this time of year (late April/early May).
  2. Find the bright Regulus in the constellation of Leo. Look for the Sickle asterism or the backwards question mark. Regulus will be the bright star at the bottom. At the time of this blog post (late April/early May) Regulus is high in the sky almost due South, just past the Meridian, towards the West, at dark. The Meridian is an imaginary line in the sky from North to South, dividing the celestial sphere into East and West.
  3. Point your binoculars or your telescope's finder almost halfway between both stars to find the cluster of stars.

Finder Chart for M44

Image Details:

Capture Date: 04/09/2023
Location: Eden, NY
Telescope: Explore Scientific ED80 Essential Series Air-Spaced Triplet Refractor
Camera: ZWO ASI2600MC Pro
Mount: Sky-Watcher USA EQ6-R Pro
Exposure: 178 exposures at 30 sec each for a total exposure of 1.48 hours / Gain 100 / Offset 50 / -10°C 
Software: NINA, SharpCap Pro, PHD2, and PixInsight



Sunday, April 2, 2023

A Journey Down a Rabbit Hole with Galaxies in my Image of M81 & M2

What led me down the Rabbit Hole?

Ok, I went down a rabbit hole on trying to identify and understand the distances to background galaxies in a recent image of the M81 & M82. I have a strong interest in finding a background galaxy that is about 380 million light years distant from Earth. Why? Well, one of the places I'm active in doing Astronomy outreach is Penn Dixie Fossil Park & Nature Reserve. The fossils found at there are about 380 million years ago. Scott Roberts from Explore Scientific calls astronomers "Hunters of Fossil Light". I find this sentiment particularly inspiring, especially due to my ties with Penn Dixie. This is what's behind my goal of finding a galaxy 380 million years away. I want to find fossil light that matches the fossils at Penn Dixie.

I recently acquired a new camera for astrophotography, a ZWO ASI2600MC Pro dedicated astronomy camera. In late February there was a rare and brief window of clear skies. Perfect for experimenting with the new camera on my imaging rig. I captured just under two hours worth of exposures on M81 & M82. The resulting image came out ok. Definitely could benefit from more time on this target. 

An astrophoto of M81 & M82 by Ernie Jacobs
Processed image of M81 & M82 from 2/25/2023

Finder chart for M81 & M82 to show their position in the night sky
Where to find M81 & M82 in the night sky.

Annotating the image in PixInsight

After processing the image in PixInsight, I plate solved the image. What is plate solving? Specialized software compares the stars in the image to a database and precisely locates the image in the night sky. This enables identification of objects contained within the field of view of the image. I used PixInsight's image annotation script to identify and display objects captured in the now solved image. I was blown away by the result.

annotated image showing many galaxies contained within the field of view of the image of M81 & M82
Annotated image of M81 & M82. Look at all of the galaxies!

Identifying the objects in the image

If you Zoom in, there is something there for almost every object identified. That something can be a smudge, a faint spot or a tiny streak. Experimenting with the annotation script, I discovered the result could output to a text file. This text file was imported into Excel and I began the process of trying to identify the light travel time for the objects identified in the image. Using Jason Guenzel's article "How To Identify Objects in Your Astrophotos" from the May 2022 issue of Astronomy Magazine as a guide, The Sinbad Astronomical Database and The NASA/IPAC Extragalactic Database (NED) were used to identify the light travel time to most of the objects identified in the annotated image. 


Object List from the annotated image of M81 & M82

In the table above, the designation of "M' indicates the object is the Messier catalog, 'NGC" New General Catalog, "PGC" Principle Galaxies Catalog, & "ARP" Arp's Atlas of Peculiar Galaxies. The distances from Earth to the main objects in the list are given in Megaparsecs (Mpc) and Million light-years (Mly), as they were easily found in Wikipedia. For the remainder of the objects, the light travel time is given in Gigayears (Gyr) form SINBAD and NED. One Gigayear is one billion light years. For example, in the table above, the light travel time for the galaxy PGC28018 is 0.215 Gyr or 215 million light-years and for PGC28056 that's 1.506 Gyr or 1.5 billion light-years. 

Mind Blown!

In this hobby it's "normal" to throw around unfathomably large numbers. I don't think our limited human experience allows us to fully appreciate the scale of these numbers. Let's look at the difference between one million and one billion as an example. One million seconds is about 10 days and one billion seconds is over 30 years! I don't know about you, but this blows my mind and is a large part of what fascinates me about this hobby.


I hope you enjoyed my trip down this rabbit hole. 


Clear Skies!
Ernie

Image Details:

Capture Date: 02/25/2023
Location: Eden, NY
Telescope: Explore Scientific ED80 Essential Series Air-Spaced Triplet Refractor
Camera: ZWO ASI2600MC Pro
Mount: Sky-Watcher USA EQ6-R Pro
Exposure: 55 exposures at 120 sec / Gain 100 / Offset 50 / -20°C each for a total exposure of 1.83 hours
Software: NINA, SharpCap Pro, PHD2, and PixInsight


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