Ok, So I Needed A Bit Of Help From A Friend Who Know More About This Than Me (unfortunately My Knowledge

Photo of Pickering's triangle (also known as Fleming's triangle) and NGC 6979 / NGC 6974 (the more diffused clouds at the top center/left). This is the third part of the Cygnus loop / veil nebula, this part of the supernova remnant is fainter than the previous two parts of the loop I photographed. This explains in part why it was only discovered by in 1904 by Williamina Fleming (whereas the two writer part were discovered in 1784 by William Herschel). Williamina Fleming was a pioneer in stellar classification, she worked with other women at the Harvard college observatory. Their work in star classification resulted in the Henry Draper Catalogue, an extensive (225 300 stars in the first edition) classification of stars with their position and their spectra. Williamina is also credited with the discovery of 59 nebula (including the famous hors head nebula) more than 300 variable stars as well as (with Henry Norris Russell and Edward Charles Pickering) the discovery of white dwarfs (the remnants of dead sun-like stars).

Photo a few galaxies, M81 / bode's galaxy (centre), M82/the cigar galaxy (left) and NGC 3077 (right)

In addition to those three galaxies, there are many other (much) smaller ones hidden among the stars (a few examples):

The red-ish filament visible around M82 are ionised hydrogen gas and dust pushed outwards by galactic-superwind

Those are tough to be a combination of solar winds created by young stars and the shockwaves of frequent supernovas. They mostly occur in starburst galaxy a type of galaxies that experience heightened stars formation generally due to recent gravitational interaction with other galaxies, in the case of M82 the trigger is most likely its neighbour M81.

(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 Ha filter. 12x180s image for each colour filter (RGB), 6x300s for the Ha filter, total imaging time 2h 54min, stacking and processing done in PixInsight.)

Photos of the two major components of the veil nebula, the first one is the eastern veil aka C33 and the second one (the one with the star in the middle) the western veil aka C34. Those are part of a supernova remnant (left over gas and dust from a supernova), their colour are due mainly to two gases present inside. The blue/green colour comes mostly from oxygen (as OIII emission around 500nm by doubly ionised oxygen) and a little bit from hydrogen (as H beta emission at 486nm) where as the red comes nearly completely from hydrogen (as H alpha emission at 656nm).

The first photo is about 2.5 hours of exposure (30x3 min for RGB + 10x5 min for H alpha) and the second one about 3 hours (36x3 min for RGB + 16x5 min for H alpha).

The additional photos taken in hydrogen alpha are added to the normal RGB photos to intensify the colour and visibility of the hydrogen gas (it doesn't show well enough with standard RGB in part due to the lower amount of light it emits an in part due to the sensor's response itself) Here is a version of C33 (eastern veil) with the stars removed as my friends were very impressed by it, hope you like it too.

Picture of the bubble nebula and surrounding objects : Top left (the vague group of stars): M52 an open cluster

Center right: NGC 7538 an emission nebula (also known as the northern lagoon nebula)

Bottom center: NGC 7635/the bubble nebula and the surrounding hydrogen cloud

The ''bubble'' part of this nebula is created by the stellar wind (flow of gas, plasma and particle) emitted by the central star at nearly 650 million km/h hitting and compressing the surrounding interstellar gas. The central star (BD +602522) is currently estimated to be about 45 times heavier than our sun and about 4 million years old. Being so massive and thus very hot (it's a type O star) its lifespan is very limited for a star and it should go supernova in about 10 to 20 million years.

BD +602522 is slightly off center from the bubble, this is due to the interstellar gas being a bit more dense on one side and thus slowing the stellar wind more efficiently.

Single exposure to make the central star more visible.

Image taken using a CarbonStar 150/600 newtonian telescope with a 0.95 coma corrector, ZWO ASI294 monochrome camera. 12x300s image for each colour filter (LRGB) and 12x300s for the Ha filter, total imaging time 5h, stacking and processing done in PixInsight.

Starless version of the same image:

Older image where the bubble is more distinct from the background hydrogen clouds :

A photo of the comet 12P ponce-brook, taken from my bedroom window. In the middle ages, comets were regarded as omens of great change, generally bad ones. It's only after the discovery of their periodic return (during the 15's to 16's hundred) and later discovery of their nature (big balls of mostly ice and some rocks orbiting the sun) that comets stoped to be feared. Despite that, I still find them to be awe-inspiring.

For those interested, this comet is currently visible with a good pair of binoculars or a telescope if you look in the Andromeda constellation (more information on positions and visibility: https://theskylive.com/12p-info) I would have taken more pictures or a better one if the clouds had not been consistently thwarting any attempts at observation in the last week and a half.

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.

There might not be sound in space, but there is quite a lot to listen to in the radio frequencies (especially when it comes to the planets of the solar system).

(the full article : https://www.jpl.nasa.gov/news/nasas-juno-spacecraft-enters-jupiters-magnetic-field ) Some ''similar'' sounds are also present on earth with for example the reverberation if radio waves emitted by lightning.

I'm trying to find a clean, concise, factual video of pulsar pulses but the top results on youtube are all fake clickbait bullshit. Where are the videos from professor so-and-so with 10 subscribers of simple black and white graphs.

(this page has what I'm looking for but afaik none of these videos are on youtube)

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.

“the arts and sciences are completely separate fields that should be pitted against each other” the overlap of the arts and sciences make up our entire perceivable reality they r fucking on the couch