AEA Astronomy Club Newsletter October
2012
Contents
AEA Astronomy Club News & Calendar p.1
Video(s) & Picture(s) of the Month p. 5
Astronomy News p. 8
General Calendar p. 10
Colloquia, lectures, mtgs. p. 10
Observing p. 11
Useful Links p. 12
About the Club p. 12
Club News & Calendar.
Calendar
AEA Astronomy Club News & Calendar p.1
Video(s) & Picture(s) of the Month p. 5
Astronomy News p. 8
General Calendar p. 10
Colloquia, lectures, mtgs. p. 10
Observing p. 11
Useful Links p. 12
About the Club p. 12
Club News & Calendar.
Calendar
Club Meeting Schedule:
18-Oct-12
|
High/Wide Dynamic Range CMOS
Imagers
|
Blake Jacquot (and Hung Ngo)
|
Aerospace
|
A1/1029A/B
|
15-Nov-12
|
Upper Atmospheric Disturbances
Using RAIDS and Ground-Based Measurements
|
Rebecca Bishop & Andrew
Christensen
|
Aerospace
|
A1/1029A/B
|
19-Dec-12
|
Beyond Next Generation Access To
Space
|
Scott Martinelli and Jay Penn
|
Aerospace
|
A1/1029A/B
|
AEA Astronomy Club meetings are on 3rd Thursdays at 11:45am. For 2012, April-May we meet in A1/1026; June-July & Oct.-Dec. in A1/1029A/B; Aug. in A1/2143 and Sept. in A3/1607A/B.
News:
16-Inch
Truss Dobs Assembly & First Light
Wed. Sept.
12 Jason Fields, a friend & I met in D8 to assemble the new 16-inch Truss
Dobsonian (see photos). After about an
hour and a half, without much trouble, we had it assembled and collimated w.
the eyepiece laser collimator. First
light came 2 nights later in the parking lot of D8 (photo).
Here
is my [Jason Fields’] report from Saturday night [Sept. 15, 2012]. Feel free to
abridge for the newsletter. [I chose not to, to show what a REAL observing
report can look like]
9/15/12 Mt Pinos
|
end of astronomical twilight
|
midnight
|
temp [deg F]
|
59
|
47
|
RH [%]
|
36
|
27
|
seeing diam [arcsec]
|
1.1
|
0.8
|
seeing (1-10)
|
5
|
4
|
transparency (1-10)
|
7
|
5
|
zenith limiting [mag]
|
6.2
|
5.9
|
zenith sky bg [mag/arcsec**2]
|
19.9
|
19.4
|
As
you can see in the table, it was a rather subpar night. In my experience a dark
mountaintop site should expect a sky brightness below 21 mag/arcsec**2 and a
zenith limiting mag of 7 or fainter. For reference, the sky brightness with a
full moon is close to 18 mag/arcsec**2. Even though the Orion Nebula would be
up within an hour, due to clearly deteriorating sky conditions I packed up
around 1 am. Neither the zodiacal glow nor Gegenschein were ever apparent and
even the Milky Way was difficult to see much north of Cepheus. Throughout the
night the seeing was poor but highly confined: small blur circles with rapid
variation in starlight intensity and color.
The transparency was also quite low and worsened as the night
progressed. It was obvious at sunset that there was a lot of dust and smoke in
the air from various fires and the Santa
Ana
All
this to say that testing the telescope was challenging.
Collimation
was challenging, in great part due to the poor seeing, evidenced quite clearly
in both in-focus, slightly out-of-focus, and grossly out-of-focus star testing,
each focus position telling me something about the collimation of the
telescope, the stability of the atmosphere, thermal currents within the
telescope (an impressive sight if you've never looked for it), etc.
There
is some flex in the spider vanes and in the secondary mirror holder which makes
precise collimation of the secondary more time-consuming than I expected.
Getting used to the primary mirror cell collimation screws (white thumbscrews)
and collimation lock screws (black thumbscrews) took a bit of time as well. It
is not difficult to find oneself putting strain on the back of the primary
mirror if one is not careful. Based on star testing, there is some evident
primary mirror sag and as well as some flex in the truss supports (the
secondary cage droops) when looking at low elevation angles.
Meade 16" f/4.5 1829 mm fl
|
magnification
|
actual FOV (calculated)
|
apparent FOV
|
|
26 mm Meade QX
|
70
|
1.00
|
70
|
|
16 mm TeleVue Nagler
|
114
|
0.72
|
83
|
|
7 mm TeleVue Nagler
|
261
|
0.31
|
83
|
|
There
is some coma when looking near the edge of field with the supplied 26-mm
eyepiece. It is not yet clear to me if this is due to the primary mirror or the
eyepiece as I did not use the drift method to measure the actual FOVs -- it was
my sense that the FOV with the 26 mm was more like 1.1 or 1.2 degrees as, for
instance, the double cluster easily fits in the FOV. The focus appeared very
flat across the entire FOV through my 16 mm Nagler. Due to the poor seeing, the
view through the 7 mm was troubled by star twinkling. Focus remained soft
throughout the night due to both atmospheric seeing and lack of precise
collimation.
Stray
light: even at a dark site, the background sky brightness from most of the
overhead sky is contributing to the background observed in the eyepiece. I
experimented a little bit with a large black cloth but results were
inconclusive other than a slightly darker background in the eyepiece. I think
the easiest baffle would either be a mask at the top of the rocker box and/or a
shroud for the open truss.
On
to the fun stuff: here is a partial list of objects observed.
object
|
type
|
notes
|
||
M26
|
open cluster
|
very rich starfield
|
||
M11
|
open cluster
|
"
|
||
M20 Trifid
|
nebula
|
very faint color; expected more vivid color; star colors were
quite evident though!
|
||
M8 Lagoon
|
nebula
|
very bright but pale; one knot of obvious pink
|
||
M24 starcloud
|
open cluster
|
numerous star colors; very nice!
|
||
Veil Nebula
|
supernova remnant
|
both halves very easy; light puple color; knots and strands very
obvious
|
||
M57
|
planetary nebula
|
Ring Nebula; very bright with little color; obvious structure
and wisps on long axis; central star mag=14.8 seen
|
||
M27
|
planetary nebula
|
Dumbbell Nebula; very bright, pink and purple; many faint stars
across disk; central star mag=13.5 seen easily
|
||
M71
|
globular cluster
|
unconcentrated; nice star colors
|
||
M10
|
globular cluster
|
well resolved
|
||
M12
|
globular cluster
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bright center
|
||
M5
|
globular cluster
|
very nice
|
||
M13
|
globular cluster
|
bright; nice star colors
|
||
6207
|
galaxy
|
easy with apparent structure and obvious dust lane; mag=12
|
||
IC 4617
|
galaxy
|
very difficult; mag=14.6; 1.2"x0.4" 550 M ly
|
||
891
|
galaxy
|
nice edge-on galaxy; fainter than expected
|
||
M31
|
galaxy
|
Andromeda Galaxy; two dust lanes very obvious; some HII and
globulars observed
|
||
M32 & 110
|
galaxy
|
Andromeda satellite galaxies; easy, apparent structure
|
||
M33
|
galaxy
|
Triangulum Galaxy; rather faint; vague teal color; some HII and
globulars observed
|
||
Double Cluster
|
open cluster
|
framed very nicely in 26 mm eyepiece
|
||
M45
|
open cluster
|
Pleiades; obvious blue reflection nebula
|
||
Jupiter
|
planet
|
too bright! need a neutral density and/or color filter; cloud
bands evident despite poor seeing
|
||
Final
thoughts:
The
telescope should not be assembled or disassembled without a second person to
assist. With a capable assistant who knows the telescope, one can set up and be
observing in minutes. Meade has done a very fine job with both the balance and
the smoothness of motion: moving the telescope while looking through the
eyepiece is very pleasant, even when tracking an object at high power. The is
extremely minimal telescope jitter or rebound when one stops moving the
telescope.
The
results of my optical testing were incomplete / inconclusive due to the poor
viewing conditions; I still have some questions about the primary mirror
figure. I suggest that a highly educational club activity would be to test the
primary mirror (Foucault knife edge test, Ronchi test, etc).
Cheers,
[Following
are in answer to M. Clayson’s question as to how he estimated/measured all
those metrics]
Briefly,
the weather data was obtained online from several sites nearby (temp, RH, and
dewpoint) and site RH was determined from the dewpoint of those sites, altitude
corrected. A rule of thumb is 3 deg F / 1,000' of elevation change in humid air
and as much as 5 deg F / 1,000' in extremely dry air. On Saturday, based on
weather data from multiple directions and elevations, the slope was 4.7 deg F /
1,000' -- very dry air indeed. I used to carry a small, old analog temp, RH,
pressure gauge and if I start "seriously" observing again, I may
return to that practice.
Seeing
diameter was determined by looking at quite a few closely spaced double stars
of known separation. Near midnight, I was able to split several 0.9"
doubles and one 0.8" double near zenith (each star of which was twinkling
rapidly but in place) but nothing at 0.7" or below.
Seeing
(1-10) and transparency (1-10) are subjective and based on nearly three decades
of observing experience. Likewise, I estimated the (naked eye) limiting zenith
magnitude and the apparent brightnesses of Polaris and Vega around midnight as
they had become noticeably fainter than normal, noted their approximate zenith
angle (Z = ~60 degrees), determined the airmass (X = sec Z
= 2), and from that came up with an approximate extinction coefficient k
from m = m0 + kX.
In
three decades of observing, I've experienced only two nights where the seeing
and transparency both rated a 10. On those nights with my 10", blue color
in the arms and yellow cores were clearly apparent in hundreds of galaxies, the
colors of hundreds of blue reflection nebula and pink emission nebula were
apparent in our Milky Way as well as several galaxies in the local group (M31,
M33, ...), Saturn was razor sharp and steady at 650x, the zodiacal light and
Gegenschein were as obvious as the Milky Way all night long, etc. For faint,
extended sources like galaxies, the seeing can be as low as 5 as long as the
transparency is 8 or better; conversely, for closely separated double stars,
planetary observing, etc, the seeing is paramount and the transparency can be
as bad as a 2. In fact, nights with high, thin altostratus clouds, which
usually belie a very stable atmosphere, can be spectacular nights for visually observing
doubles and planets but are of course terrible nights for photometry and for
visually observing faint, extended sources. So, I find it important to gauge
both the seeing and transparency as they both affect what kind of observing can
be done.
As
far as mirror testing, it is inexpensive and not too difficult to assemble
various test setups; again, it might be useful and instructive for the club to
do this.
Not
listed in my observations from Saturday night were probably a dozen other
Messier objects, probably a dozen Cr (Collinder) open clusters, a few Barnard
dust clouds in Sagittarius and Ophiuchus, a few more globular clusters, and
numerous galaxies mostly in Pegasus.
Jason
Mallincam
Extreme Video Camera First Light
Friday Sept.
21 I was on the road to Las Vegas when the Shuttle was flying over L.A. That evening I set up the LX-200 &
videocamera for a 1-hour presentation to about 15 young Boy Scouts & their
leaders at my brother’s request. I'd arranged for someone to also bring a
large-screen TV, table & generator (amazingly quiet & long cord) for
it, and we set up in a parking lot.
Shortly before the boys arrived at 8pm, and after making all the connections, doing the LX-200 alignment & commanding to go to the moon, I was pleasantly amazed to see a huge, sharp (after focusing) image of about one-eighth of the moon filling the large screen monitor (& a small preview window on my laptop). See attached photo. It was like looking out of the window of an orbiting spacecraft as I slewed w. the directional buttons on the LX-200 controller.
Shortly before the boys arrived at 8pm, and after making all the connections, doing the LX-200 alignment & commanding to go to the moon, I was pleasantly amazed to see a huge, sharp (after focusing) image of about one-eighth of the moon filling the large screen monitor (& a small preview window on my laptop). See attached photo. It was like looking out of the window of an orbiting spacecraft as I slewed w. the directional buttons on the LX-200 controller.
The boys were amazingly well-behaved (according to their leaders, and I agree) -- clearly impressed w. the moon image upon arrival, asking astronomical questions but also about the equipment cost, etc. I first oriented them in the sky using the laser pointer (Polaris & diurnal motions, constellations & bright stars, ecliptic & Milky Way, etc.). Then I took them on a GoTo tour (the LX-200 was hitting objects spot on in the FOV), showing examples (Messier & NGC) of open & globular clusters, nebula, & galaxy (no visible planets), and explaining the astronomy merit badge requirements (I’m a certified counselor). I need to learn to finesse the gain/exposure on the DSO's, as there was difficulty getting sharp images w. them -- possibly also an artifact of the monitor (I understand CRT monitors are better), as well as the thin cirrus and heat turbulence? And I thought I'd captured a screen shot, but think I forgot a menu item or 2. But all within an hour, w/out long lines at an eyepiece.
Looking forward to a great large-screen show of the sun w. the H-alpha scope at the AEA October Festival.
Green
Flash!
After a
lifetime of failed attempts, Mark Clayson finally saw the green flash Sat.
Sept. 29 from Crystal Cove Beach in Newport Beach. Unfortunately, no photo for proof, but my
sister & brother-in-law visiting from Cody, Wyoming, can vouch as they also
saw it.
Astronomy
Video(s) & Picture(s) of the Month
(from Astronomy Picture of
the Day, APOD: http://apod.nasa.gov/apod/archivepix.html) Video(s)
Astronomy News:
NASA's Chandra shows Milky Way is surrounded
by halo of hot gas
NASA/CXC/M.Weiss;
NASA/CXC/Ohio State/A.Gupta et al.
Baryons are particles, such as protons and neutrons, that make up more than 99.9 percent of the mass of atoms found in the cosmos. Measurements of extremely distant gas halos and galaxies indicate the baryonic matter present when the universe was only a few billion years old represented about one-sixth the mass and density of the existing unobservable, or dark, matter. In the current epoch, about 10 billion years later, a census of the baryons present in stars and gas in our galaxy and nearby galaxies shows at least half the baryons are unaccounted for.
In a recent study, a team of five astronomers used data from Chandra, the European Space Agency's XMM-Newton space observatory and Japan's Suzaku satellite to set limits on the temperature, extent and mass of the hot gas halo. Chandra observed eight bright X-ray sources located far beyond the galaxy at distances of hundreds of millions of light-years. The data revealed X-rays from these distant sources are absorbed selectively by oxygen ions in the vicinity of the galaxy. The scientists determined the temperature of the absorbing halo is between 1 million and 2.5 million kelvins, or a few hundred times hotter than the surface of the sun.
Other studies have shown that the Milky Way and other galaxies are embedded in warm gas with temperatures between 100,000 and 1 million kelvins. Studies have indicated the presence of a hotter gas with a temperature greater than 1 million kelvins. This new research provides evidence the hot gas halo enveloping the Milky Way is much more massive than the warm gas halo.
"We know the gas is around the galaxy, and we know how hot it is," said Anjali Gupta, lead author of The Astrophysical Journal paper describing the research. "The big question is, how large is the halo, and how massive is it?"
To begin to answer this question, the authors supplemented Chandra data on the amount of absorption produced by the oxygen ions with XMM-Newton and Suzaku data on the X-rays emitted by the gas halo. They concluded that the mass of the gas is equivalent to the mass in more than 10 billion suns, perhaps as large as 60 billion suns.
"Our work shows that, for reasonable values of parameters and with reasonable assumptions, the Chandra observations imply a huge reservoir of hot gas around the Milky Way," said co-author Smita Mathur of Ohio State University in Columbus. "It may extend for a few hundred thousand light-years around the Milky Way or it may extend farther into the surrounding local group of galaxies. Either way, its mass appears to be very large."
The estimated mass depends on factors such as the amount of oxygen relative to hydrogen, which is the dominant element in the gas. Nevertheless, the estimation represents an important step in solving the case of the missing baryons, a mystery that has puzzled astronomers for more than a decade.
Although there are uncertainties, the work by Gupta and colleagues provides the best evidence yet that the galaxy's missing baryons have been hiding in a halo of million-kelvin gas that envelopes the galaxy. The estimated density of this halo is so low that similar halos around other galaxies would have escaped detection.
The paper describing these results was published in the Sept. 1 issue of The Astrophysical Journal. Other co-authors were Yair Krongold of Universidad Nacional Autonoma de Mexico in Mexico City; Fabrizio Nicastro of Harvard-Smithsonian Center for Astrophysics in Cambridge, Mass.; and Massimiliano Galeazzi of University of Miami in Coral Gables, Fla.
NASA's Marshall Space Flight Center in Huntsville, Ala., manages the Chandra program for NASA's Science Mission Directorate in Washington. The Smithsonian Astrophysical Observatory controls Chandra's science and flight operations from Cambridge.
For Chandra images, multimedia and related materials, visit: http://www.nasa.gov/chandra
General Calendar:
Colloquia, Lectures, Seminars, Meetings, Open Houses & Tours:
Colloquia: Carnegie (Tues. 4pm), UCLA,
Caltech (Wed. 4pm), IPAC (Wed. 12:15pm) & other Pasadena (daily 12-4pm):
http://obs.carnegiescience.edu/seminars/
Carnegie astronomy lectures – only 4 per year in the Spring www.obs.carnegiescience.edu. Visit
www.huntington.org for directions. For more information about the Carnegie
Observatories or this lecture series, please contact Reed Haynie.
|
5 Oct
|
SBAS Monthly
General Meeting at El Camino College planetarium. 7:30 PM
Topic: “Looking for Life on Mars and Other Places”
Speaker: Dr. Max Coleman, JPL/CalTech:. http://www.sbastro.net/.
|
Oct. 11 & 12 The von Kármán Lecture Series: 2012
Herschel
Opens Up the Cool Universe
The
Herschel Space Observatory, launched on May 14, 2009, is designed to carry out
astronomical observations at wavelengths from ~1mm to 100 microns. This region
of the spectrum, between radio waves and heat radiation, is a unique probe of
the “cool” universe, that is, of objects at temperatures between a few degrees
and 100 degrees above absolute zero. This includes material out of which new
stars are forming in locations ranging from distant galaxies to nearby cold
clouds of gas. To carry out these observations, Herschel has the largest
precision telescope launched for astronomy, and three very sensitive
instruments. Among many projects, Herschel has followed the “water trail” –
observing this molecule in a wide range of sources ranging from giant molecular
clouds to protoplanetary disks around young stars to comets in the solar system.
This talk will present some of the highlights of Herschel observations and
describe how they are changing our picture of how new stars and planets form.
Speaker:
|
Dr. Paul Goldsmith |
Locations:
|
Thursday, Oct 11,
2012, 7pm The von Kármán Auditorium at JPL 4800 Oak Grove Drive Pasadena, CA › Directions Friday, Oct 12, 2012, 7pm The Vosloh Forum at Pasadena City College 1570 East Colorado Blvd. Pasadena, CA › Directions |
Webcast:
|
We offer two options to
view the live streaming of our webcast on Thursday: › 1) Ustream with real-time web chat to take public questions. › 2) Flash Player with open captioning If you don't have Flash Player, you can download for free here. |
18-Oct-12
|
High/Wide Dynamic Range CMOS
Imagers
|
Blake Jacquot (and Hung Ngo)
|
Aerospace
|
A1/1029A/B
|
22 Oct
|
LAAS LAAS General Meeting.
|
Griffith
Observatory
Event Horizon Theater 8:00 PM to 10:00 PM |
Observing:
The following
data are from the 2012 Observer’s Handbook, and Sky & Telescope’s 2012 Skygazer’s
Almanac & monthly Sky at a Glance.
A weekly 5 minute video about what’s up in the night sky: www.skyandtelescope.com/skyweek.
Sun,
Moon & Planets for October:
Moon: Oct 8 last quarter, Oct 15 new, Oct
22 1st quarter, Oct 29 full
Other
Events:
5 Oct. Jupiter 0.9 deg N. of moon
6 Oct
|
SBAS Star Party (weather permitting): RPV at
Ridgecrest Middle School 28915 North Bay Rd.
|
8-9 October Draconid Meteor Shower
Expect a peak rate of 10 yellow meteors per hour under
clear, moonless conditions. These are fairly
slow meteors, coming in at 12.5 miles per second. They
radiate from the head of the constellation
Draco. This shower was once known as the Giacobinids.
13-27 Oct Zodiacal Light visible before morning twilight.
13 Oct
|
LAAS Dark Sky Night : Lockwood Valley (Steve Kufeld Astronomical Site; LAAS members and their guests
only)
|
13 Oct
|
SBAS
out-of-town observing – contact Greg Benecke http://www.sbastro.net/.
|
17, 18 Oct – Mercury 1.3 deg S. of moon, Mars 2
deg S. of moon
20 Oct
|
Public Star Party: Griffith Observatory Grounds
2-10pm
|
20-22 October Orionids Meteor Shower
This shower produces a peak rate of 20 yellow and green
meteors per hour, which are fast moving
at 41.6 miles per second and are known to produce
fireballs. They radiate from a point in the sky
not far from Orion’s red giant star Betelgeuse. Best pre-dawn.
26 Oct Mercury at
greatest eastern elongation – 24 deg from the sun (in the evening)
Internet Links:
Link(s) of the Month
Link(s) of the Month
General
Mt. Wilson Institute (www.mtwilson.edu/), including status for visits & roads
About the Club
Club Websites: Internal (Aerospace): https://aeropedia.aero.org/aeropedia/index.php/Astronomy_Club It is updated to reflect this newsletter, in addition to a listing of past club mtg. presentations, astronomy news, photos & events from prior newsletters, club equipment, membership & constitution. We have linked some presentation materials from past mtgs. Our club newsletters are also being posted to an external blog, “An Astronomical View” http://astronomicalview.blogspot.com/.
Club Websites: Internal (Aerospace): https://aeropedia.aero.org/aeropedia/index.php/Astronomy_Club It is updated to reflect this newsletter, in addition to a listing of past club mtg. presentations, astronomy news, photos & events from prior newsletters, club equipment, membership & constitution. We have linked some presentation materials from past mtgs. Our club newsletters are also being posted to an external blog, “An Astronomical View” http://astronomicalview.blogspot.com/.
Membership. For information, current dues & application, contact Jim Johansen, or see the club website where a form is also available. Benefits will include use of club telescope(s) & library/software, discounts on Sky & Telescope magazine and Observer’s Handbook, field trips, great programs, having a say in club activities, acquisitions & elections, etc.
Committee Suggestions & Volunteers. Feel free to contact: Paul Rousseau, Program Committee Chairman (& club VP), TBD, Activities Committee Chairman (& club Secretary), or Jim Johansen, Resource Committee Chairman (over equipment & library, and club Treasurer).
Mark Clayson,
AEA Astronomy Club President
