December 26, 2012
NGC 1999, the Keyhole Nebula (Dec. 12, 2012)
This is NGC 1999, the Keyhole Nebula. It is a reflection nebula lit by the star on the right edge of the lower part of the keyhole. The nebula is so bright there that it is difficult to see the star separately from the nebula.
The interesting thing about the Keyhole Nebula is that it is actually a hole. Many dark spots seen against a brighter nebular background are cold clouds of gas and dust. Not so the Keyhole, apparently. The keyhole feature appears actually to be a hole. Deep images with a variety of infrared scopes (reported here) show that in the keyhold feature there lurks ... nothing. What blasted a hole through this patch of otherwise brightly lit cloud? That is a mystery, but the area is full of young stars just beginning stellar life. Perhaps one of them blasted a tunnel right through.
Mine is not a deep image. Surrounding the blue reflection nebula is a lot more gas and dust that is not lit up so brightly with reflected light. Some more interesting objects my image only begins to show are also brighter in other pictures of the region. You can see some of them in Adam Block's image, here, taken with a much larger scope from the top of a very dark mountain. In my image you can see just a hint of these other things in the reddish background and in the red glowing objects just to the right of the Keyhole Nebula.
Telescope: Orion 254mm f/4.7 Newtonian and RCC I
Camera and Exposure: SXVF-H9 (R: 9x240"; B: 10x240" (synthetic green)), T-shirt flats
Filter: Astronomik RB, IDAS-LPS2
Guiding: SX Lodestar and SX OAG
Mount: Takahashi NJP
Software: Nebulosity, Maxim DL, Registar, Photoshop CS3
Location: The Woodlands, TX
December 19, 2012
Rosette Nebula and NGC 2244 (Dec. 17, 2012)
This is second light with the AT111EDT. This is just H-alpha. I hope to go back for OIII and perhaps SII in the coming months.
Telescope: Astro-Tech AT111EDT and William Optics P-FLAT4 (eff. at f/5.6)
Camera and Exposure: SXVF-H9C (10x900"), Alnitak Flat-man flats
Filter: Astronomik 12nm Ha [+NII]
Guiding: SX Lodestar and SX OAG
Mount: Takahashi NJP
Software: Nebulosity, Maxim DL, Photoshop CS3
Location: The Woodlands, TX
M1 (Dec. 12, 2012)
In 1054 A.D. , Chinese astronomers noted a new star in the sky. It shone so brightly that folks could see it in the daytime. But the star was temporary. In fact, it was not a new star at all but an old star that exploded. This nebula is the result of that explosion. M1 is a supernova remnant. It is one of the coolest deep sky objects in the heavens.
Why so cool? Well, first, this is one of the few deep sky objects whose origin was observed by human beings, and it's been growing ever since. Most objects in the sky change very slowly by our time scale, but not this one. In fact, some amateur astronomers have observed changes in M1 in their own images over time.
Second, M1 is not just a supernova remnant. It is the home of what is left of the star that exploded. The core of the supernova did not have enough mass to become a black hole, so it stopped just short of that and became a neutron star. Within it, gravity's power has overcome the forces that create space within atoms, crushing the elements away. What is left is a ball of neutrons only 15-18 miles wide that contains more mass than the Sun! Pretty heavy stuff!
But there is more. The neutron star and its interactions with its immediate environment produce more than just visible light. Radio waves, x-rays, and gamma rays all stream out of the center of M1. See NASA's combined optical and x-ray image of the center of M1 here. The neutron star's intense radiation causes this to happen.
Even more remarkably, the neutron star is spinning very quickly. It's strong electromagnetic field concentrates the radio waves into pulses that tick like a clock in space. When astronomers first heard it, its regularity suggested that astronomers were receiving a signal from aliens. But theorists later determined how a neutron star could produce such pulses. We call such a spinning neutron star a pulsar.
The pulsar itself is visible in this image. At the center of the nebula are two stars, easily visible next to each other. The pulsar is the dimmer of the two, on the right. We may not have a picture of a black hole yet, but we have images of the next closest thing. How cool is that?
This image is a combination of (1) a stack of frames taken through an H-alpha filter with (2) a short color image I took a year ago through the same telescope. I have simply slapped the color over the H-alpha image. Here is the H-alpha alone:
Here is the capture data for the H-alpha image:
Telescope: Orion 254mm f/4.7 Newtonian and RCC I
Camera and Exposure: SXVF-H9 (H-alpha: 10x900"), T-shirt flats
Filter: Astronomik 12nm Ha
Guiding: SX Lodestar and SX OAG
Mount: Takahashi NJP
Software: Nebulosity, Maxim DL, Registar, Photoshop CS3
Location: The Woodlands, TX
The color data is described here.
Why so cool? Well, first, this is one of the few deep sky objects whose origin was observed by human beings, and it's been growing ever since. Most objects in the sky change very slowly by our time scale, but not this one. In fact, some amateur astronomers have observed changes in M1 in their own images over time.
Second, M1 is not just a supernova remnant. It is the home of what is left of the star that exploded. The core of the supernova did not have enough mass to become a black hole, so it stopped just short of that and became a neutron star. Within it, gravity's power has overcome the forces that create space within atoms, crushing the elements away. What is left is a ball of neutrons only 15-18 miles wide that contains more mass than the Sun! Pretty heavy stuff!
But there is more. The neutron star and its interactions with its immediate environment produce more than just visible light. Radio waves, x-rays, and gamma rays all stream out of the center of M1. See NASA's combined optical and x-ray image of the center of M1 here. The neutron star's intense radiation causes this to happen.
Even more remarkably, the neutron star is spinning very quickly. It's strong electromagnetic field concentrates the radio waves into pulses that tick like a clock in space. When astronomers first heard it, its regularity suggested that astronomers were receiving a signal from aliens. But theorists later determined how a neutron star could produce such pulses. We call such a spinning neutron star a pulsar.
The pulsar itself is visible in this image. At the center of the nebula are two stars, easily visible next to each other. The pulsar is the dimmer of the two, on the right. We may not have a picture of a black hole yet, but we have images of the next closest thing. How cool is that?
This image is a combination of (1) a stack of frames taken through an H-alpha filter with (2) a short color image I took a year ago through the same telescope. I have simply slapped the color over the H-alpha image. Here is the H-alpha alone:
Telescope: Orion 254mm f/4.7 Newtonian and RCC I
Camera and Exposure: SXVF-H9 (H-alpha: 10x900"), T-shirt flats
Filter: Astronomik 12nm Ha
Guiding: SX Lodestar and SX OAG
Mount: Takahashi NJP
Software: Nebulosity, Maxim DL, Registar, Photoshop CS3
Location: The Woodlands, TX
The color data is described here.
Subscribe to:
Posts (Atom)