Picture Of The Bubble Nebula And Surrounding Objects : Top Left (the Vague Group Of Stars): M52 An Open

I took another photo of the crescent nebula (C27) this time using my monochrome camera and processed similarly to my photos of the veil nebula. The H-alpha photos really helped to enhance the ionised hydrogen present in this region of space (deep red clouds in the background). Still not completely satisfied with how the stars turned out (too much halo visible around them), could have been mitigated if the clouds had not come half way through the imaging session or if I do another night of imaging of this target.

A quick and (very) dirty mosaic of the H alpha photos I had already taken for the three major components of the Cygnus loop.

I wanted to have an idea of what a future mosaic of this target could look like (probably won't be able to do better than that before the end of the year or next summer unfortunately)

Thought I could post it here while I finish processing newer photos.

Since the weather has been cloudy and rainy for about a month now (not a single night where I could take decent photos), here is a photo of the sun from last summer.

Despite the sun just looking like a bright ball of light at first glance, there are actually quite a lot of things to see on it.

This photo was taken using a specific light filter that enhances the details of the sun's surface. All of those black spots are sunspots, regions of the sun that are colder due to local magnetic fields preventing some of the heat from reaching the surface. The slightly brighter regions visible on the side of the sun are solar plage, zones that are slightly hotter, also due to the local magnetic fields.

Finally, the surface of the sun in the picture looks a bit granular/wrought, that is due to solar granulation, smaller (around 1000 km in width) convection currents (basically bubble of plasma) at the surface. (The resolution isn't great so the granulation is not super clearly visible, unfortunately).

Ok, so I finished the processing of my new photo of the Flaming Star Nebula (IC 405)

Image taken in SII and Ha with a few RGB images to have the correct star colours. This is technically an SHH combination image but with a narrowband normalisation and a lot of curve modifications (with and without colour masks) to get colours/contrast that I liked. I already had taken a photo of this nebula, but it was using mostly RGB data with a bit of Ha (and a lot less integration time). It did show the dust reflection way better, but I like the contrast we can see inside the nebula's gas on this one. Thanks to @shaythempronouns for suggesting the use of an SII filter to image this nebula. Starless version :

(Image taken using a CarbonStar 150/600 newtonian telescope with a 0.95 coma corrector, ZWO ASI294 monochrome camera ZWO LRGB filters and Baader 6.5nm narrowband filter. 5x120s image for each colour filter (RGB), 29x300s for the Ha filter and 33x300s for the SII filter, total imaging time 6h 35min, stacking and processing done in PixInsight. Photo taken mid-January)

Image of IC 405 aka the Flaming Star Nebula This is an emission (the red part) and reflection (the blue part) nebula. It's relatively bright for a nebula with visual magnitude of +6.

The bright star at the center of the blue reflection nebula is AE Aurigae, it's the star responsible for the ionisation of the gas in this nebula. AE Aurigae is what's known as a runaway star, those are star that moves at high speed compared to their surrounding environment. They are the result of gravitational interaction between stars or stars being ejected by nearby supernovae. In the case of AE Aurigae, it was probably ejected due to gravitational interaction, its path has been traced back to the Orion Nebula from which it was ejected about 2 million years ago.

The moon was nearly full and somewhat close by when I took the photos, so it was a bit tricky to process them. As a result, the reflection part of the nebula was not as visible as I would have liked but I think the overall result is not too bad.

Image taken using a CarbonStar 150/600 newtonian telescope with a 0.95 coma corrector, ZWO ASI294 monochrome camera. 6x300s image for each colour filter (LRGB) and 12x300s for the Ha filter, total imaging time 3h, stacking and processing done in PixInsight.

Tried applying the Ortonglow script in PixInsight to give the nebula a bit more depth, but I don't like the halos it gave around the bright stars on the left.

This is a photo of the Andromeda galaxy I took nearly 5 years ago. The dark parts of the galaxy are gigantic clouds of dust and gas in which no stars and planets are born. This galaxy is one the closest one to our own, and yet it's 2.55 million light years from us, It's composed of about 1000 billion stars, in a few billion years it will collide with our own galaxy.

The two lighter blotches around Andromeda are two satellite Galaxys that orbit around Andromeda and are also composed of millions of stars.

Those numbers are so big they start to get inconceivable, and that's only a small fraction of what exists out-there. We are not much in the grand scheme of the universe, but when you look at the night sky and the wonders of the universe you can feel at least for a little while that you're part of it.

Photo of the NGC 2237, the Rosette nebula and the star cluster inside it, NGC 2244.

The star cluster, which is estimated to be about 5 million years old, is responsible for the ionisation of the surrounding gas. The mass of the nebula is estimated to be about 10 000 times the mass of our sun, which is relatively massive for a diffuse nebula.

This image uses a SHO palette, I quite like the colours I manage to get, both as the normal and starless images.

I also tried using the Foraxx palette, I think it's a bit less interesting visually, but the dark dust structures seam a bit more visible.

(Image taken using a CarbonStar 150/600 newtonian telescope with a 0.95 coma corrector, ZWO ASI294 monochrome camera ZWO LRGB filters and Baader 6.5nm SHO filter. 5x120s image for each colour filter (RGB), 15x300s for the Ha filter 20x300s for the SII filter and 18x300s for the OIII filter, total imaging time 4h 25min, stacking and processing done in PixInsight.)

Those do not look like much, but they are, to the best of my knowledge, Herbig-Haro object (to left: HH 94, top right: HH 249 and bottom: HH 95) Herbig-Haro object are ionised gas clouds formed when the jet of hot plasma ejected at the poles of newly born stars interacts with Interstellar gas, they are thus more common in star forming regions. I first noticed one of them (HH 94) after I shared the image with a friend. The What's in my image PixInsight scrip from SetiAstro was very useful in finding out what that was. I couldn't find a lot of information on those objects specifically (and very few pictures), but a few publications did have images to compare with (orientation differs):

(original publication ref for HH 94 & HH 95; additional publication ref for HH294 aka NGC 2023 HH 3) (better images of other Herbig-Haro object taken by Hubble : 1, 2 & 3) Position of the three objects in the original image (another might be present but I wasn't confident they were visible):

Photo of the Iris nebula / Caldwell 4 / NGC 7023, I'm very pleased with this one since I finally managed to capture the surrounding dust (barely visible in the 2 previous attempts). This is a reflection nebula, this means that it's a dust cloud reflecting the light from a nearby star. Being one of the brightest reflection nebula visible in the northern hemisphere it's visible in relatively small telescopes (4-6 inch / 100-150mm diameter), unfortunately the outer dust clouds can only be seen on photos. Reflection nebula generally tend to be blue due to a more efficient scattering of blue light compared to red by the dust particles (M45 in my previous post is another good example).