what's black and white and red all over?
...an image using an Ha filter.
due
to the abundance of hydrogen, you'll get some signal all the way from
the highest energy to the lowest energy regions in a nebula right up to
the ionization front, with rare exceptions. thus hubble pallet images
using SII, Ha, and OIII are typically teal and gold rather than red
green and blue.
I chose a M76, a relatively bright planetary nebula with some detail, for the first image with my new narrower Helium II filter (4nm from chroma).
a quick blink of the mono channels for this one showed me that the brightest signal areas were not quite completely separated
which means a scientifically assigned color pallet will give the full spectrum...
a rainbow in space:
Helium II blue, (so faint it's stretched), Oxygen III linear green, Nitrogen II linear red
here's the color image with a log stretch which works quite well for bright planetaries with faint shells:
a healthy does of NII was applied as luminance
here's another variant with OIII assigned to teal rather than green:
mono NII
mono OIII
Helium II as blue with a green continuum filter as red and green (both new filters):
stretched blink
still looking for the pot of gold
8" LX200R, SX Trius 694 and QSI 660 binnedx2 to 0.8"/px
astrodon 3nm NII, 3nm OIII, chroma 4nm Helium II filters
ASA DDM60
NII 35x20min OIII 17x20min HeII 27x20 min
11/2014-2/2015
never enough exposure time...
Try increasing gamma if dark sections aren't distinguished
Tuesday, March 17, 2015
Saturday, February 14, 2015
planetary nebula IC 418: a blue gem in a red cocoon
here's my first light with a new ccd camera: starlight xpress trius 694
believe it or not i've never used a filter wheel before
just manually screwed one filter on, imaged for a few nights, then went on to the next
not a big deal for super long narrow band imaging, but inconvenient for quick bright planetaries
so the filter wheel that came with the camera is more of a novelty to me
than the larger, more sensitive chip
thus a quick shot of a bright planetary as first light.
after seeing IC 418 listed as one of winter's best planataries in feb S&T
i decided to revisit the red planetary with narrow band filters
as my prior rgb effort yielded nothing but a red disk with a brighter spot in the center
so here it is in NII/OIII/OIII:
it's difficult to make out the central structure at native image scale
so i upsampled x2
for a final resolution of (EDIT: 0.2"/px) (makes a difference to my eye)
straight linear stretch with a bit of RL deconvolution
in OIII there is a disk with a subtle central brightening:
here's the NII which shows a central star with an outer shell:
blink
difficult to say whether the mottling is noise or a hint of the spirograph pattern detected in the hubble image
interestingly combining the NII and OIII in a color image
seems to create an unsharp mask like effect
making the central OIII brightening (gem) more evident
prior effort (RGB 2007):
i also shot HeII subs but found only a very faint ring around the central star
seemed matched continuum filter images with equivalent exposure (accounting for bandwidth)
meaning it's either broadband glow or artifact such as reflections, corrector plate dust etc.
of course after imaging it i came across this on Jim Kaler's web site
indicating there are no HeII emissions:
http://stars.astro.illinois.edu/sow/ic418.html
"The low excitation nebula, with its relatively cool central star, does not exhibit He II emission lines (those of ionized helium), just those of He I (neutral helium)"
i believe this is taken from a 50 year old reference:
From L.H. Aller and J.B. Kaler, Astrophysical Journal vol. 140, p. 936, 1964.
so i'm a bit behind the times...
i also shot a 20 minute sub binned x2 in NII and OIII
and found no evidence of any other outer shell (didn't check Ha)
8" LX200R, SX Trius 694 0.4"/px
astrodon 3nm NII, 3nm OIII filters
NII 22x30s, OIII 20x30s
ASA DDM60
no AO no guiding
1/2/15
believe it or not i've never used a filter wheel before
just manually screwed one filter on, imaged for a few nights, then went on to the next
not a big deal for super long narrow band imaging, but inconvenient for quick bright planetaries
so the filter wheel that came with the camera is more of a novelty to me
than the larger, more sensitive chip
thus a quick shot of a bright planetary as first light.
after seeing IC 418 listed as one of winter's best planataries in feb S&T
i decided to revisit the red planetary with narrow band filters
as my prior rgb effort yielded nothing but a red disk with a brighter spot in the center
so here it is in NII/OIII/OIII:
it's difficult to make out the central structure at native image scale
so i upsampled x2
for a final resolution of (EDIT: 0.2"/px) (makes a difference to my eye)
straight linear stretch with a bit of RL deconvolution
in OIII there is a disk with a subtle central brightening:
here's the NII which shows a central star with an outer shell:
blink
difficult to say whether the mottling is noise or a hint of the spirograph pattern detected in the hubble image
interestingly combining the NII and OIII in a color image
seems to create an unsharp mask like effect
making the central OIII brightening (gem) more evident
prior effort (RGB 2007):
i also shot HeII subs but found only a very faint ring around the central star
seemed matched continuum filter images with equivalent exposure (accounting for bandwidth)
meaning it's either broadband glow or artifact such as reflections, corrector plate dust etc.
of course after imaging it i came across this on Jim Kaler's web site
indicating there are no HeII emissions:
http://stars.astro.illinois.edu/sow/ic418.html
"The low excitation nebula, with its relatively cool central star, does not exhibit He II emission lines (those of ionized helium), just those of He I (neutral helium)"
i believe this is taken from a 50 year old reference:
From L.H. Aller and J.B. Kaler, Astrophysical Journal vol. 140, p. 936, 1964.
so i'm a bit behind the times...
i also shot a 20 minute sub binned x2 in NII and OIII
and found no evidence of any other outer shell (didn't check Ha)
8" LX200R, SX Trius 694 0.4"/px
astrodon 3nm NII, 3nm OIII filters
NII 22x30s, OIII 20x30s
ASA DDM60
no AO no guiding
1/2/15
Thursday, February 12, 2015
Comet Lovejoy C/2014 Q2
caught a bright comet with an impressive tail in January:
The image frame is approximately 2 degrees wide, making this the longest comet tail I've captured as it clearly departs the frame. Some images from dark skies show a tail spanning 19 degrees.
This was shot through heavy light pollution and passing clouds (explaining the gaps in the star trails). Nevertheless, the bright, twin tail structure is still visible.
The comet was easily visible in binoculars, brighter than the andromeda galaxy, though i could not detect the tail.
Here's a video of the individual frames complete with clouds and airplanes:
Note the comet tail follows the direction of the solar wind rather than the comet motion in this instance.
Though fading a bit from peak brightness
It should still be visible early evening in Andromeda this weekend with the new moon approaching
FS60C@ f/42. with SX H9C color camera and chroma light pollution filter. 60x2 minute exposures with mount tracking on comet (ASA DDM 60).
Sunday, January 4, 2015
speaking of gas giants...Uranus
Uranus, seventh planet from the Sun. It has the third-largest radius and fourth-largest mass in the Solar System. Uranus is similar in composition to Neptune. Along with Neptune, sometimes called an "ice giant" (prior post). It has the coldest planetary atmosphere in the Solar System, with a minimum temperature −224 °C. It has a complex, layered cloud structure, with water thought to make up the lowest clouds, and methane the uppermost layer of clouds. At 20 a.u. it has an 84 year orbit. Like other gas giants it spins rapidly, making one revolution in 17 hours.
Uranus has an axial tilt of 98°, so its axis of rotation is approximately parallel with the plane of the Solar System. This gives it bizarre seasonal changes. Combine this extreme tilt with it's 84 year orbit and you get a 21 year "night" at the pole during winter, compared to a 17 hour day at the equator during equinox.
Like Neptune, there's not much to see visually. Unlike Neptune, it can be seen with the unaided eye in dark locations. At high power it can be seen as a small disk rather than a dot. A slightly more green than Neptune. A monster telescope or camera might detect several moons (see below), and possibly faint cloud formations.
The Hubble or flyby space craft can detect faint rings.
Uranus has an axial tilt of 98°, so its axis of rotation is approximately parallel with the plane of the Solar System. This gives it bizarre seasonal changes. Combine this extreme tilt with it's 84 year orbit and you get a 21 year "night" at the pole during winter, compared to a 17 hour day at the equator during equinox.
Like Neptune, there's not much to see visually. Unlike Neptune, it can be seen with the unaided eye in dark locations. At high power it can be seen as a small disk rather than a dot. A slightly more green than Neptune. A monster telescope or camera might detect several moons (see below), and possibly faint cloud formations.
Uranus and moons 10/19/06 05:32 UTC |
The Hubble or flyby space craft can detect faint rings.
Saturday, January 3, 2015
Neptune overview
Neptune--eighth
and farthest planet from the Sun (after Pluto’s demotion). Along with Jupiter, Saturn and Uranus, a gas
giant. Smaller, but slightly more massive than its
near-twin Uranus. Uranus and Neptune are sometimes referred to as "ice giants" as they contain a higher proportion of "ices" such as water, ammonia, and methane. Traces
of methane in the outer atmosphere account for the planet's blue
appearance. At 30 au its orbit around
the sun takes 165 years, so it’s not moving much in the sky from year to
year.
Discovered
in 1846, Neptune was the first planet found by mathematical prediction rather
than by empirical observation. Unexpected changes in the orbit of Uranus suggested
gravitational perturbation by another planet. There’s been controversy over
credit for the discovery:
Interestingly,
Galileo made the first recorded observation of Neptune, but apparently did not
recognize it as a planet, though some have suggested that he was aware that it
had moved relative to fixed stars.
For visual
astronomers, there’s not much to see except for the fact that at high power it
can be seen as a small bluish disk rather than a dot. It generally cannot be seen with the unaided eye. Due to its distance, its apparent size is the
smallest of the planets. With dark skies
or a camera you may be able to pick up a few moons.
Here’s an
image of Neptune, the white spot to the right is its large moon triton:
With the
Hubble or flyby space craft, surface storms and very faint rings have been
detected.
Monday, December 22, 2014
wiffed on einstein's cross: happy solstice
Gravitational lensing is a phenomenon predicted by einstein's general theory of relativity wherein the warp in space due to the gravitational field of a large galaxy or group of galaxies causes a magnification or lensing effect upon light from a galaxy that is more distant.
einstein's cross a/k/a cgcg378-15 is a galaxy who's lensing effect splits the image of a distant background quasar into four separate images.
i've been trying to image this elusive structure for years. failing time and time again to even find it. last year, i thought i'd caught it, but entered the incorrect catalog number, imaging the wrong galaxy (cgcg 378-14 instead of cgcg 378-15):
this year i'm sure i actually caught the right galaxy:
though the core doesn't look quite round, i certainly can't claim to have resolved the cross. There do appear to be interesting reddish Ha emissions in the spiral arms.
this one stays on the list for next year.
PS what i should see is 4 dots in the center instead of one. the dots represent the single distant quasar viewed through the distorted lens of the galaxy's gravitational field.
Here's a shot from a professional observatory with a an aperture measured in meters:
here's the Hubble super close up of the core only
with a little imagination, a close look at the core suggests it's not quite round, but not convincing enough to say i'm seeing the lensing effect.
PS what i should see is 4 dots in the center instead of one. the dots represent the single distant quasar viewed through the distorted lens of the galaxy's gravitational field.
Here's a shot from a professional observatory with a an aperture measured in meters:
here's the Hubble super close up of the core only
with a little imagination, a close look at the core suggests it's not quite round, but not convincing enough to say i'm seeing the lensing effect.
happy solstice xmas and hanukka
details:
8" LX200R, SX AO, SX H9/H9C, .6"/px
IDAS LPR filter
lum 113x5 min, RGB 13x20 min
9/2014
Newport Beach, CA
IDAS LPR filter
lum 113x5 min, RGB 13x20 min
9/2014
Newport Beach, CA
Thursday, November 27, 2014
North America and Pelican Nebulae
North America and Pelican Nebulae
The North America Nebula is a huge emission nebula in Cygnus close to the bright star Deneb.
It took me years to see it through a telescope, even from dark skies. At 4 times the size of the full moon, i was staring right at the middle of it with my long focal length telescope. Finally i used a filter in the small low power finder scope on top and caught it.
This image is a two frame mosaic with my shortest focal length telescope, showing the North American nebula to the left, and the pelican nebula to the right of a central patch of dust.
This image uses the "hubble pallet" with high energy oxygen as blue, low energy sulfur as red, and hydrogen as green.
not entirely happy with the framing as i've clipped the west coast in order to include the pelican :(
might try again next year
Here it is with an alternative pallet using only high energy oxygen as blue and low energy sulfur as red (hydrogen was used in part as luminance):
Here's an older close up of the "cygnus wall" aka "gulf of mexico"
and the Pelican
Takahashi FS60c @255mm CS 8.6nm Ha, AD 3nm OIII, AD 3nm SII, SX H9
2 frame mosaic total time Ha 49x5 min, OIII 74x10 min, SII 92x10 min
Newport Beach, CA 10/2014
The North America Nebula is a huge emission nebula in Cygnus close to the bright star Deneb.
It took me years to see it through a telescope, even from dark skies. At 4 times the size of the full moon, i was staring right at the middle of it with my long focal length telescope. Finally i used a filter in the small low power finder scope on top and caught it.
This image is a two frame mosaic with my shortest focal length telescope, showing the North American nebula to the left, and the pelican nebula to the right of a central patch of dust.
This image uses the "hubble pallet" with high energy oxygen as blue, low energy sulfur as red, and hydrogen as green.
not entirely happy with the framing as i've clipped the west coast in order to include the pelican :(
might try again next year
Here it is with an alternative pallet using only high energy oxygen as blue and low energy sulfur as red (hydrogen was used in part as luminance):
Here's an older close up of the "cygnus wall" aka "gulf of mexico"
and the Pelican
Takahashi FS60c @255mm CS 8.6nm Ha, AD 3nm OIII, AD 3nm SII, SX H9
2 frame mosaic total time Ha 49x5 min, OIII 74x10 min, SII 92x10 min
Newport Beach, CA 10/2014
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