View allAll Photos Tagged PlanetaryNebula
Fought with the drive, fought against the weather... and mostly lost. My target was M101 (which I have imaged before) with the hope of determining what the Supernova now looks like. But M101 is low in the North West sky at sunset and that is the worst light pollution direction from my backyard.
Since I've been teaching Astrophotography 101 I feel it is important to represent what is achievable using very modest equipment - including the failures.
Clouds came and I quickly repointed nearly straight up into Lyra where I knew I'd find the tiny object known as the Ring Nebula (aka M57, NGC 6720). After spending about 10 minutes getting it framed near the center of my field of view I was only able to get 3 45-second exposures before dew and clouds ended the evening.
If you've ever watched the TV show "Big Bang Theory" featuring a bevy of nerds you've probably seen this planetary nebula on the wall of the apartment. However that image is big and colorful - it was captured with a large scope at high magnification.
I'll be adding this feature to my "how big is it" series comparing the sizes of various objects in the sky to the moon. The Ring Nebula is about 1.4 arc minutes or 84 arc seconds. How does that compare with Jupiter? Jupiter is about half the size at 49 arc seconds.
I may be deceiving myself, but it appears that despite the horrible light pollution, and imprecise drive alignment I appear to have caught the central star that formed this "planetary" nebula. It's notoriously difficult to see except in large aperture scopes. Of course, it could just be noise since with so few exposures, the noise from 1000 ISO 45 second exposures is not small.
This object is actually very easy to find. It's lined up right between two of the brightest stars in Lyra.
© Copyright 2011, Steven Christenson blog Events
All rights reserved. Curious what "all rights reserved means?" it means that without written permission you may not: copy, transmit, modify, use, print or display this image in any context other than as it appears in Flickr.
This is a restacking of the previous image processed on just a portion of the overall image so that I could use the 3x Drizzle setting in Deep Sky Stacker to try and improve the resolution of the nebula.
Also tried a couple new tools in The Gimp for cleaning up noise, setting the black point etc.
The photo consists of 30x 20 second exposures at ISO1600 on a Canon T1i DSLR at prime focus on a 10 inch SN-10AT telescope using a light pollution filter. 10 minutes total exposure time.
The Helix Nebula is a very large planetary nebula located in Aquarius. It is one of the closest planetary nebula to earth, but the largely Ha emission of the nebula combined with light pollution and poor Ha (infrared) response of my camera made this very difficult to photograph.
Total integrated exposure is a tad under 6 hours. 2min subs.
Taken on Celestron C8 at f/6.3 with a Nikon D800
Telescope: Celestron Ultima 8 with PEC
Location: Locust Valley
Camera: Hutech modified Canon Rebel XT
ISO: 1600
Exposure: 28 images at 10 seconds each.
Each frame was taken unguided at prime focus through the telescope. The frames were stacked using MaxDSLR. Additional processing was handles with Photoshop.
It's a planetary nebula located about 1000 light years away in the constellation of Vulpecula. Like M57, it was created when a star similar to our own hit old age and puffed off it's outer layers.
Without a camera, just looking through the telescope, no colour is apparent. It just looks like a fuzzy patch faintly dumbell shaped, no sign of the outer shell.
The photo consists of 30x 20 second exposures at ISO1600 on a Canon T1i DSLR at prime focus on a 10 inch SN-10AT telescope using a light pollution filter. 10 minutes total exposure time. Photo stacked with Deep Sky Stacker. Cleaned up a little with Gimp.
I tried to take more care with this one, limiting the exposure length to try and keep the stars looking sort of like stars, although they are still kind of squiggly.
This is Minkowski 3-35, a complex-looking little planetary nebula. it is 225% original size (I made it 150% and then decided to do 150% again). This image was taken by the WFPC2 instrument on the Hubble Space Telescope.
Alone in the dark!
HST/HLA, NASA/ESA, Nikolaus Sulzenauer
HST_9463_78_ACS_HRC_F606W
HST_9463_78_ACS_HRC_F814W
This is a crop of the 'widefield' version, I'm very pleased with the amount of detail retained and for just 10 minutes worth of data!
Discovered in July 1764 by Charles Messier. M27 lies 1000 light years away.
The Dumbbell Nebula (also known as the Apple Core Nebula, Messier 27, or NGC 6853) is a planetary nebula in the constellation Vulpecula, at a distance of about 1,360 light years. (Wikipedia)
This object was the first planetary nebula to be discovered by Charles Messier in 1764. It is a popular target for amateur observation. It is 2.5 light-years across, and is the result of a supernova explosion about 10,000 years ago.
The central star, a white dwarf, is estimated to have a radius which is 0.055 R☉ which gives it a size larger than any other known white dwarf. The central star mass was estimated to be 0.56 M☉. (Wikipedia)
This was a joint project with Ariel.
Press "L" to view large on black
Edited Hubble Space Telescope montage of two planetary nebulae.
Original caption: Hubble was recently retrained on NGC 6302, known as the "Butterfly Nebula," to observe it across a more complete spectrum of light, from near-ultraviolet to near-infrared, helping researchers better understand the mechanics at work in its technicolor "wings" of gas. The observations highlight a new pattern of near-infrared emission from singly ionized iron, which traces an S shape from lower left to upper right. This iron emission likely traces the central star system Ãs most recent ejections of gas, which are moving at much faster speeds than the previously expelled mass.
The star or stars at its center are responsible for the nebula's appearance. In their death throes, they have cast off layers of gas periodically over the past couple thousand years. The "wings" of NGC 6302 are regions of gas heated to more than 36,000 degrees Fahrenheit that are tearing across space at more than 600,000 miles an hour.
NGC 7027's central star was identified in a new wavelength of light ó near-ultraviolet ó for the first time by using Hubble's unique capabilities. The near-ultraviolet observations will help reveal how much dust obscures the star and how hot the star really is.
This object, which resembles a colorful jewel bug, is a visibly diffuse region of gas and dust that may be the result of ejections by closely orbiting binary stars that were first slowly sloughing off material over thousands of years, and then entered a phase of more violent and highly directed mass ejections. Hubble first looked at this planetary nebula in 1998. By comparing the old and new Hubble observations, researchers now have additional opportunities to study the object as it changes over time.
Data taken June 2014 in Leicester
SW 150 PDS, EQ5 Pro Synscan GOTO and Modified Canon 600D.
Guiding: SW ST80 and QHY5
Using: BYEOS, PHD, DSS and Photoshop CC.
ISO 400
10 x 60s lights 5 x 60s darks
10 x 30s lights 5 x 30s darks
5 x 120s lights 2 x 120s darks
2 x 180s lights 1 x 180 darks
1 x 240s lights 1 x 240s darks
Vicky Norton
This is a stunning planetary nebula that proves the ESO archive is hiding quite a few treasures (not that that needed proving). Abell 24 is actually a relatively popular target for astronomers in comparison to the other Abell nebulae. The nebulosity is pretty strongly visible in Hydrogen Alpha, but very faint in most other wavelengths. No oxygen! It looks like a rose.
This one presented a bit of a challenge for me to process. Initially, I tried to include older OIII data from EFOSC2, but I just couldn't make it work. I'm sure a processor much better than myself could do it though! I may try again as I learn more. I did fill the gaps of missing data with the older EFOSC2 exposures.
I apologise for my apparent laziness in writing captions (and maybe even the processing of the images).
red: vlt/fors2 h_alpha
green: vlt/fors2 v_high
blue: vlt/fors2 b_high
Gemini Observatory image of Kronberger 61 showing the ionized shell of expelled gas resembling a soccer ball. The light of the nebula is primarily due to ionized oxygen (oxygen-III) emission and its central star can be seen as the slightly bluer star very close to the center of the nebula. The field of view is 2.2 x 3.4 arcminutes with north up (rotated 22 degrees west of north). Image processing by Travis Rector, University of Alaska Anchorage. A color composite image, it consists of two narrow-band images (O-III and Hydrogen-alpha with three, 500-second integrations each) obtained with the Gemini Multi-Object Spectrograph (GMOS) on the Gemini North telescope on Mauna Kea in Hawai‘i. Below the bright star at left is a barred spiral galaxy in the distant background, careful inspection will reveal several additional distant galaxies in the image.
A rework of the stack taken on June 13-14, 2012. I created more temperature matched darks with the cooled camera. Only set left from the old library is the 14C. If I ever get enough of those to try again, I may revisit this data. At this point, because of the flaws in the lights, I think I'm finished with this target for the season.
Restacked in DSS 3.3.3 beta 47 with best 85% filter applied. This gives 24 lights that are "better" even with the light leaks. Focus is not perfect on several of the lights so that's what I hoped to remove with the 85% setting.
As before, this is a stack of images of the M57 region as taken through an Orion 127mm Maksutov Cassegrain telescope with a full-spectrum modified Pentax K10D camera. The camera is further modified with a peltier device to cool hot spots on the body to help keep thermal noise to a minimum. Baader Moon and Skyglow filter used to control some LP. Lights are 10 minutes at 400 ISO. Guiding done via SSAG on Orion ST80 on Losmandy GM8 mount. Off center position because of slop in the DEC axis.
After stacked, I brought the FIT into PI where I ran deconvolution, then DBE, then 200x iterations of masked stretches, then a few rounds of curves, then ACDNR. Final step of solving and annotating before exporting to LR 3.
Image Plate Solver script version 1.51
==================================================
Referentiation Matrix (Gnomonic projection = Matrix * Coords[x,y]):
+0.000024753523 +0.000225118281 -0.276562916275
-0.000225158051 +0.000024794168 +0.373793262939
+0.000000000000 +0.000000000000 +1.000000000000
Resolution ........ 0.815 arcsec/pix
Rotation .......... -96.275 deg
Focal ............. 1366.01 mm
Pixel size ........ 5.40 um
Field of view ..... 48' 13.0" x 28' 5.4"
Image center ...... RA: 18 53 23.321 Dec: +32 56 18.56
Image bounds:
top-left ....... RA: 18 52 03.895 Dec: +33 18 42.66
top-right ...... RA: 18 52 29.604 Dec: +32 30 47.68
bottom-left .... RA: 18 54 17.557 Dec: +33 21 47.99
bottom-right ... RA: 18 54 42.078 Dec: +32 33 51.34
Another rough shot on the night I got my telescope back from repairs.
13x 30 second exposures, 6.5 minutes total exposure time. ... Obviously could have centered it better to avoid the field curvature.
M57 is a planetary nebula ... a shell of gass puffed off of a star similar to our star but near the end of it's life. A last hoorah before fading out as a white dwarf.
PK 2-9.1
Planetary nebula in Sagittarius
Source: Hubble Legacy Archive
hst_08345_56_wfpc2_f656n_pc
hst_08345_56_wfpc2_f658n_pc
Processed version of an image from the Hubble Space Telescope of NGC 6818, a planetary nebula called the Little Gem Nebula.
Original caption: This colourful bubble is a planetary nebula called NGC 6818, also known as the Little Gem Nebula. It is located in the constellation of Sagittarius (The Archer), roughly 6000 light-years away from us. The rich glow of the cloud is just over half a light-year across — humongous compared to its tiny central star — but still a little gem on a cosmic scale. When stars like the Sun enter retirement, they shed their outer layers into space to create glowing clouds of gas called planetary nebulae. This ejection of mass is uneven, and planetary nebulae can have very complex shapes. NGC 6818 shows knotty filament-like structures and distinct layers of material, with a bright and enclosed central bubble surrounded by a larger, more diffuse cloud. Scientists believe that the stellar wind from the central star propels the outflowing material, sculpting the elongated shape of NGC 6818. As this fast wind smashes through the slower-moving cloud it creates particularly bright blowouts at the bubble’s outer layers. Hubble previously imaged this nebula back in 1997 with its Wide Field Planetary Camera 2, using a mix of filters that highlighted emission from ionised oxygen and hydrogen (opo9811h). This image, while from the same camera, uses different filters to reveal a different view of the nebula. A version of the image was submitted to the Hubble’s Hidden Treasures image processing competition by contestant Judy Schmidt.
This is a super clear image of tiny planetary nebula Henize 2-138. The central star looks a little strange.
Data used: hst_06353_15_wfpc2_total_pc
A beautiful, small planetary nebula captured by Hubble only through F656N. I'm really curious about what this nebula would look like in colour.
This image was enlarged to 150% original size. I don't really want to enlarge any images to more than that.
Data used: hst_06353_29_wfpc2_f656n_pc
Gemini image of the planetary nebula NGC 246, the Skull Nebula.
Image source: Gemini/AURA (and modified by me)
There's definitely a much better way to do this, but I don't know it yet. I haven't tried combining narrowband and wideband data before.
This nebula was imaged for proposals 6119 & 8307.
150% original size.
North is up.
Red: hst_06119_36_wfpc2_f814w_pc + hst_08307_01_wfpc2_f658n_pc
Green: hst_08307_01_wfpc2_f656n_pc
Blue: hst_06119_36_wfpc2_f555w_pc + hst_08307_01_wfpc2_f502n_pc
Gemini Observatory image of Kronberger 61 showing the ionized shell of expelled gas resembling a soccer ball. The light of the nebula is primarily due to ionized oxygen (oxygen-III) emission and its central star can be seen as the slightly bluer star very close to the center of the nebula. The field of view is 2.2 x 3.4 arcminutes with north up (rotated 22 degrees west of north). Image processing by Travis Rector, University of Alaska Anchorage. A color composite image, it consists of two narrow-band images (O-III and Hydrogen-alpha with three, 500-second integrations each) obtained with the Gemini Multi-Object Spectrograph (GMOS) on the Gemini North telescope on Mauna Kea in Hawaiâi. Below the bright star at left is a barred spiral galaxy in the distant background, careful inspection will reveal several additional distant galaxies in the image.
PK 352-7.1
Planetary nebula in Corona Australis.
Source: Hubble Legacy Archive
hst_08345_13_wfpc2_f656n_pc
hst_08345_13_wfpc2_f658n_pc
Edited Spitzer Space Telescope image of the Helix Nebula. Color/processing variant.
Original caption: A dying star is throwing a cosmic tantrum in this combined image from NASA's Spitzer Space Telescope and the Galaxy Evolution Explorer (GALEX), which NASA has lent to the California Institute of Technology in Pasadena. In death, the star's dusty outer layers are unraveling into space, glowing from the intense ultraviolet radiation being pumped out by the hot stellar core.
This object, called the Helix nebula, lies 650 light-years away, in the constellation of Aquarius. Also known by the catalog number NGC 7293, it is a typical example of a class of objects called planetary nebulae. Discovered in the 18th century, these cosmic works of art were erroneously named for their resemblance to gas-giant planets.
Planetary nebulae are actually the remains of stars that once looked a lot like our sun. These stars spend most of their lives turning hydrogen into helium in massive runaway nuclear fusion reactions in their cores. In fact, this process of fusion provides all the light and heat that we get from our sun. Our sun will blossom into a planetary nebula when it dies in about five billion years.
When the hydrogen fuel for the fusion reaction runs out, the star turns to helium for a fuel source, burning it into an even heavier mix of carbon, nitrogen and oxygen. Eventually, the helium will also be exhausted, and the star dies, puffing off its outer gaseous layers and leaving behind the tiny, hot, dense core, called a white dwarf. The white dwarf is about the size of Earth, but has a mass very close to that of the original star; in fact, a teaspoon of a white dwarf would weigh as much as a few elephants!
The glow from planetary nebulae is particularly intriguing as it appears surprisingly similar across a broad swath of the spectrum, from ultraviolet to infrared. The Helix remains recognizable at any of these wavelengths, but the combination shown here highlights some subtle differences.
The intense ultraviolet radiation from the white dwarf heats up the expelled lay
This is a very stunning planetary nebula and it makes me wonder how many are still waiting to be found in the archive. Hundreds? It looks like this one had multiple outbursts which would explain that gorgeous chaotic appearance. Also that arc to the left is pretty interesting. I really hope I got the filters right on this one, I kept second-guessing myself, but I think this was the best result. This is the first time I can think of where the WFC3/UVIS instrument was used to conduct a planetary nebula survey. I really need to focus on my school work now, so I think this will be the last one for a while.
Red: hst_11657_80_wfc3_uvis_f814w
Green: hst_11657_80_wfc3_uvis_f350lp
Blue: hst_11657_80_wfc3_uvis_f200lp + hst_11657_80_wfc3_uvis_f502n
Equipment: Nikon D5300, Tamron SP 70-300mm f/4-5.6 Di VC USD lens, and iOptron Skytracker. Taken at 300mm, f/8.0, ISO 8000, 49 frames of 60 seconds each plus 30 darks. Stacked in Regim and cropped/processed in Lightroom.
M27 Dumbell Nebula-2012.09.05-Canon EOS450D-11.5mins-ISO 1600-16 subs-DSS-Gimp2.8-Neat Image. This set of exposures were taken with the camera piggy backed on my telescope.
This is yet another beautiful planetary nebula and I really like the halo-ish concentric-ish rings around it. It also has quite an interesting shape.
North is up and this image is of original size.
Red: F656N
Green: No layer used
Blue: F658N
Finally having some good success with autoguiding my C6.
M27 - The Dumbbell nebula
C6S-GT at F10, 8x3min, Canon 30D at ISO 1600
Guided with a DSI Pro and PHD guiding.
Combination of Hubble Space Telescope and Chandra Space Telescope images showing the planetary nebula NGC 2392. The pink region in the center is from the Chandra image (which shows x-rays).
A very tiny bipolar planetary nebula.
These data were collected for proposal 8345
This image was enlarged to 150% its original size.
Red: hst_08345_31_wfpc2_f658n_pc
Green: pseudo
Blue: hst_08345_31_wfpc2_f656n_pc
Another night of data added, bringing the total number of subframes up to 29.
This larger number of lights has helped smooth out the background. It's also helped identify the problem areas with other lights and the library of darks. The amp glow in the northern section of the frame comes from bad darks. I'll have to make a few new ones that match the temperature range of 14-17 C. Also, there were light leaks getting in on some of the subs, causing large arcs to streak across the field.
I did a little different processing on this image to try to get more from the better data. I applied a curve to the image after DBE and masked stretch. There were two curves - one for RGB and another for L. The L curve was a little hotter, bringing up some lightness of small stars. I also added some passes of sharpening and better noise reduction.
As usual, I brought the tif files into LR for a final tweak before uploading.
Here's the output from the PI image solve:
Referentiation Matrix (Gnomonic projection = Matrix * Coords[x,y]):
+0.000024749075 +0.000225128501 -0.276575132022
-0.000225173446 +0.000024803937 +0.373822748842
+0.000000000000 +0.000000000000 +1.000000000000
Resolution ........ 0.815 arcsec/pix
Rotation .......... -96.275 deg
Focal ............. 1365.93 mm
Pixel size ........ 5.40 um
Field of view ..... 48' 13.2" x 28' 5.5"
Image center ...... RA: 18 53 23.314 Dec: +32 56 18.62
Image bounds:
top-left ....... RA: 18 52 03.888 Dec: +33 18 42.78
top-right ...... RA: 18 52 29.592 Dec: +32 30 47.60
bottom-left .... RA: 18 54 17.556 Dec: +33 21 48.19
bottom-right ... RA: 18 54 42.072 Dec: +32 33 51.34
This wideband data was not collected with the intent of seeing the nebulosity, but instead the binary central star. This means that there are quite a few ground-based images which are much clearer in seeing the nebula as a whole. However, the data does provide some interesting detail in its very tight frame. Since this was a rather dull two-colour image, I added some ground-based data for colour enhancement. I hope that's ok. I could have manipulated it to match, but I thought that would probably be even worse.
M76 is most commonly referred to as the Little Dumbbell Nebula, named for its supposed resemblance to the much larger Dumbbell Nebula. This one isn't exactly a hidden treasure, it was published for a collection of the Hubble's observations of Messier objects. Still, I thought it deserved more attention and, of course, I am skipping none.
Note: saturation was very slightly increased
See the Hubble-only version here.
Luminosity+Colour:
Red: WFPC2 F814W
Green: pseudo
Blue: WFPC2 F555W
+ Colour:
Mount Lemmon Sky Centre (already processed by Adam Block)
The ring nebula, or M57 to astrogeeks, is a planetary nebula. This is a medium-sized dying star's last throws, as it expells gas and collapses on itself to become a white dwarf. The dying star can just be seen in the middle of the nebula. This process will happen to our sun in a few billion years. Taken unguided through a Celestron 14" telescope on a Software Bisque mount with a modified Canon 450D, with about 21 minutes total exposure. A friend of mine has access to an academic observatory, and she is nice enough to let me in and fire up the scope for me from time to time! Thanks Jaz! It's an amazing piece of equipment and so much fun to use!
This NASA Hubble Space Telescope image shows one of the most complex planetary nebulae ever seen, NGC 6543, nicknamed the "Cat's Eye Nebula." Hubble reveals surprisingly intricate structures including concentric gas shells, jets of high-speed gas and unusual shock-induced knots of gas. Estimated to be 1,000 years old, the nebula is a visual "fossil record" of the dynamics and late evolution of a dying star. A preliminary interpretation suggests that the star might be a double-star system. The suspected companion star also might be responsible for a pair of high-speed jets of gas that lie at right angles to this equatorial ring. If the companion were pulling in material from a neighboring star, jets escaping along the companion's rotation axis could be produced. These jets would explain several puzzling features along the periphery of the gas lobes. Like a stream of water hitting a sand pile, the jets compress gas ahead of them, creating the "curlicue" features and bright arcs near the outer edge of the lobes. The twin jets are now pointing in different directions than these features. This suggests the jets are wobbling, or precessing, and turning on and off episodically. This color picture, taken with the Wide Field Planetary Camera-2, is a composite of three images taken at different wavelengths. (red, hydrogen-alpha; blue, neutral oxygen, 6300 angstroms; green, ionized nitrogen, 6584 angstroms). The image was taken on September 18, 1994. NGC 6543 is 3,000 light- years away in the northern constellation Draco. The term planetary nebula is a misnomer; dying stars create these cocoons when they lose outer layers of gas. The process has nothing to do with planet formation, which is predicted to happen early in a star's life.
The Dumbbell Nebula (also known as Apple Core Nebula, Messier 27, M 27, or NGC 6853) is a planetary nebula in the constellation Vulpecula, at a distance of about 1,360 light years.
Taken with 14.5" f7.0 RCOS telescope mounted on a Paramount ME, FLI PL16K camera at -35C, 80 mins of RGB, 150 mins of Luminance.
6 usable lights (60s), 10 darks, 20 flats, 20 bias. Canon EOS 450D DSLR prime focus, ISO1600. Baader Neodymium filter and coma corrector. Sky-Watcher 150P Explorer on EQ3-2 mount. DeepSkyStacker > PixInsight > PhotoShop.
This is M20, the Trifid Nebula. It's interesting because the pink and blue colors are very distinct when imaging this target. This lies in the dense star fields of Sagittarius and lies close by to M8, the Lagoon Nebula, and at the top of the image, M21, which got cut off when I cropped it. This is a result of over 30 minutes of exposures.
06/16/12
Joshua Tree National Park, CA
70 frames = 31 min 58 second exposure ISO 6400
Processed in DeepSkyStacker and Gimp 2
6" Meade Newtonian Reflector LXD75 EQ Mount
Canon Rebel T3 DSLR
Canon EOS 450D 20x 20s subs ISO800 Prime focus Skywatcher 150 Explorer Newtonian. Processed in DeepSkyStacker, PixInsight and Photoshop CS5