This deep sky object is called the Crab Nebula. It is a supernova remnant that was the first Messier Object – M1. It is located in the Constellation Taurus and is a Milky Way Galaxy resident that is about 6500 light years away. Messier was tired of finding objects like this when he was searching for Comets, so he devised a list of deplorables like this in order to avoid them in the future. I managed to tease out some interesting detail in M1 by using three extremely narrow… band filters (Oxygen, Hydrogen and Nitrogen) and assigning them to colors that would enhance the detail in the image. One advantage of narrow band filters is that they filter out moon glow which was almost at it’s peak during these imaging sessions. The 25 stacked exposures totaled about 12.5 hours through a six inch refractor at f8 with a 1200mm focal length. More details are available at my Astrobin site. http://astrob.in/287183/0/
This is a mosaic of 18 separate panels taken through an H-Alpha filter with the Rokinon 135mm f2.0 lens piggy backed on the Celestron C11 telescope. Each panel was produced by stacking 20 images comprised of 5 and 10 minute exposures. The total exposure time was 45 hours. The picture includes the Veil Nebula, North American Nebula, Pelican Nebula, Tulip Nebula, Propeller Nebula and the Crescent Nebula in the Constellation Cygnus. Microsoft ICE was used to assemble the mosaic. Other software that was used included Adobe Photoshop, Pixinsight, and Maxim DL.
Some things look best when they are photographed with a 135mm lens.
“The Rho Ophiuchi cloud complex is a dark nebula of gas and dust that is located 1° south of the star ρ Ophiuchi of the constellation Ophiuchus. At an estimated distance of 131 ± 3 parsecs, this cloud is one of the closest star-forming regions to the Solar System.
This cloud covers an angular area of 4.5° × 6.5° on the celestial sphere. It consists of two major regions of dense gas and dust. The first contains a star-forming cloud (L1688) and two filaments (L1709 and L1755), while the second has a star-forming region (L1689) and a filament (L1712–L1729). These filaments extend up to 10–17.5 parsecs in length and can be as narrow as 0.24 parsecs in width. Some of the structures within the complex appear to be the result of a shock front passing through the clouds from the direction of the neighboring Sco OB2 association.
Temperatures of the clouds range from 13–22 K, and there is a total of about 3,000 times the mass of the Sun in material. Over half of the mass of the complex is concentrated around the L1688 cloud, and this is the most active star-forming region. There are embedded infrared sources within the complex. A total of 425 infrared sources have been detected near the L1688 cloud. These are presumed to be young stellar objects, including 16 classified as protostars, 123 T Tauri stars with dense circumstellar disks, and 77 weaker T Tauri stars with thinner disks. The last two categories of stars have estimated ages ranging from 100,000 to a million years.”
More info is available at Astrobin.
This is the color version of yesterday’s solar image.
The solar disk is a stacked composite of 10000 images and the prominence is a composite of 1000 images taken with the 80mm Lunt Solar Scope and a video cam at 8 frames per second.
This was taken today with the Lunt 80mm solar telescope. The best of 10000 images were stacked. They were taken with a video cam at a rate of 8/second.
Below is a link to my Astrobin gallery. After about a year and a half of acquiring and processing images I finally made it to the Astrobin “leaderboard” which is reserved for the top 100 Astrophotographers out of 5000+ contributors from all over the world. Given that I am always dumbfounded by what those in the top 10 are able to accomplish, I am happy to at least be a placeholder in the top 100. The nice thing about Astrobin is that you can see what equipment and processes others are using to produce their images. Then you just learn by doing. Some Astrobin contributors are just getting started and have a few images taken with a modest telescope and a videocam or dslr. Others have sophisticated setups in dark sky areas. Some even use source material from the Hubble or large professional telescopes. I am amazed by what some people can accomplish with the smallest of setups in the most light polluted cities. It is an interesting place to browse and learn.
This was taken with an 80mm Lunt Solar telescope and a Dakin 2.4x Barlow.
Shown below are three new versions of the Sombrero Galaxy. The original data involved a total imaging time of 5.6 hours and 79 photos through LRGB filters and the Celestron EdgeHD 11.
“The Black Eye Galaxy (also called Evil Eye Galaxy; designated Messier 64, M64, or NGC 4826) was discovered by Edward Pigott in March 1779, and independently by Johann Elert Bode in April of the same year, as well as by Charles Messier in 1780. It has a spectacular dark band of absorbing dust in front of the galaxy’s bright nucleus, giving rise to its nicknames of the “Black Eye” or “Evil Eye” galaxy. M64 is well known among amateur astronomers because of its appearance in small telescopes. It is a spiral galaxy in the Coma Berenices constellation.”
This was taken through the Celestron EdgeHD 11 inch telescope. A total of 138 images were stacked for a total imaging time of 7.5 hours