The Hubble Ultra Deep Field Image (see description on the right, below)

The Hubble Ultra Deep Field Image
(10,000 galaxies in an area 1% of the apparent size of the moon -- see description on the right, below)

Monday, June 9, 2014

2014 June

AEA Astronomy Club Newsletter June 2014

Contents
AEA Astronomy Club News & Calendar p.1
Video(s) & Picture(s) of the Month p. 2
Astronomy News p. 8
General Calendar p.10
    Colloquia, lectures, mtgs. p. 10
    Observing p. 12
Useful Links p. 13

About the Club p. 14

Club News & Calendar.

Calendar

Club Meeting Schedule:

19 June 2014
Club Meeting
 "Zooming into the center of our Galaxy: Of Black Holes and Gas Clouds".
Leo Meyer, UCLA
A1/1735
17 July 2014
Club Meeting
Helioseismology
Edward Rhodes, USC
A1/1735
21 Aug 2014
Club Meeting
A Tour of the new Aerospace E POD (A6) Telescope & Facility
Richard Rudy
Gather in A6 Lobby then to          E Pod






AEA Astronomy Club meetings are on 3rd Thursdays at 11:45am.  For all of 2014 except May, the meeting room is A1/1735.

News:  

Our June 19 meeting features "Zooming into the center of our Galaxy: Of Black Holes and Gas Clouds," by UCLA professor Leo Meyer, visiting from Germany.  The meeting will be in A1/1735 at 11:45.

Stay tuned for a summer star party combined with the camera & video club. 

 

Newest acquisitionKodak PlayFull Dual (Zi12) Video and 12 MP Camera 

Purchased primarily to videorecord club meeting presentations, but also to document activities, and it may be used for astrophotography just as cell phone cameras, especially with the eyepiece bracket.  Also purchased a case, 2 spare batteries & charger, 32 Gb memory card, external microphone & screen protector.  Other features:
·         Two powerful cameras in one - shoot spectacular 1080p HD video @ 60 fps or take stunning pictures with the 12 MP BSI CMOS sensor
·         Enhance your shots in dimly lit situations with the built-in Xenon flash
·         Record and review audio with remarkable fidelity via the external microphone/headphone jack
·         Grab all the details using high speed video @ 240 fps or 120 fps for slow motion playback
·         Relive moments instantly on the 3 in. HVGA LCD featuring KODAK Color Science technology and Glare Shield
·         Built-in USB connector for quick upload


The A6 E Pod telescope completion has continued to suffer schedule delays, and so once again our tour is being put off to Aug 21, when Rick Rudy of the Remote Sensing Dept. will give us a tour of the new in-house-built telescope in the A6 E Pod.   See the Orbiter story on the new telescope here: http://pages.aero.org/orbiter/2013/08/12/in-house-telescope-provides-new-capabilities/


Astronomy Video(s) & Picture(s) of the Month
(from Astronomy Picture of the Day, APOD: http://apod.nasa.gov/apod/archivepix.html)


VIDEO:  Illustris Simulation of the Universe http://apod.nasa.gov/apod/ap140512.html  
Video Credit: 
Illustris Collaboration, NASA, PRACE, XSEDE, MIT, Harvard CfA; 
Music: The Poisoned Princess (
Media Right Productions)
Explanation: How did we get here? Click play, sit back, and watch. A new computer simulation of the evolution of the universe -- the largest and most sophisticated yet produced -- provides new insight into how galaxies formed and new perspectives into humanity's place in the universe. The Illustris project -- the largest of its type yet -- exhausted 20 million CPU hours following 12 billion resolution elements spanning a cube 35 million light years on a side as it evolved over 13 billion years. The simulation is the first to track matter into the formation of a wide variety of galaxy types. As the virtual universe evolves, some of the matter expanding with the universe soon gravitationally condenses to form filaments, galaxies, and clusters of galaxies. The above video takes the perspective of a virtual camera circling part of this changing universe, first showing the evolution of dark matter, then hydrogen gas coded by temperature (0:45), then heavy elements such as helium and carbon (1:30), and then back to dark matter (2:07). On the lower left the time since the Big Bang is listed, while on the lower right the type of matter being shown is listed. Explosions (0:50) depict galaxy-center supermassive black holes expelling bubbles of hot gas. Interesting discrepancies between Illustris and the real universe do exist and are being studied, including why the simulation produces an overabundance of old stars.

VIDEO:  An ALMA Telescope Array Time-Lapse http://apod.nasa.gov/apod/ap140526.html
Video Credit: 
ESO, José Francisco Salgado, NRAO; Music: Flying Free (Jingle Punks)
Explanation: It is the most expensive and complex ground-based astronomy project ever -- what will it see tonight? The Atacama Large Millimeter Array (ALMA) project consists of 66 dishes, many the size of a small house, situated in the high altitude Atacama Desert in Northern Chile. Together, ALMA observes the skies in high-frequency radio light, a band usually used only for local communication due to considerable absorption by humid air. The thin atmosphere and low humidity above ALMA, however, enable it to see deep into our universe in new and unique ways that allow, for example, explorations of the early universe for chemicals involved in star formation, and observing local star systems for signs of disks that form planets. The above time-lapse video shows the course of four ALMA antennas over one night. The Moon sets early in the video, while three dishes repoint in unison. Background stars continually rotate up, the central band of our Milky Way Galaxy pivots around and eventually exits off to the right, while halfway through the Small and Large Magellanic Clouds -- satellite galaxies near our Milky Way -- rise up from below the horizon. Car headlights momentarily illuminate the dishes, while an occasional Earth-orbiting satellite crosses overhead. Daylight ends the video but not ALMA observations -- which typically run both all night and all day.

VIDEO:  A Live View from the International Space Station http://apod.nasa.gov/apod/ap140514.html
Credit: 
NASA, UStream, HDEV Project
Explanation: If you were floating above the Earth right now, this is what you might see. Two weeks ago, the robotic SpaceX Dragon capsule that delivered supplies to the Earth-orbiting International Space Station (ISS) also delivered High Definition Earth Viewing (HDEV) cameras that take and transmit live views of Earth. Pictured above, when working, is the live video feed that switches between four cameras, each pointed differently. Watch white clouds, tan land, and blue oceans drift by. The above video will appear black when it is nighttime on the Earth below, but the space station's rapid 90-minute orbit compresses this dark time into only 45 minutes. The present location of the ISS above the Earth can be found on the web. If the video appears gray, this indicates that the view is either being switched between cameras, or communications with the ISS is temporarily unavailable. As the HDEV project continues, video quality will be monitored to assess the effects of high energy radiation, which types of cameras work best, and which Earth views are the most popular. Although this feedwill eventually be terminated, lessons learned will enable better cameras to be deployed to the ISS in the future, likely returning even more interesting live feeds.

VIDEO:  A Supercell Storm Cloud Forming over Wyoming http://apod.nasa.gov/apod/ap140521.html
Video Credit: 
Basehunters (BasehuntersChasing) Music: Empire (Shakira)
Explanation: How do supercell storm clouds form? Pictured above is a time-lapse video taken last Sunday detailing the formation of one such violent supercell in eastern Wyoming, USA. Starting as part of a large and dark thunderstorm complex, the supercell comes together along with a large rotating updraft of air known as a mesocyclone. Mesocyclones form during rapid changes in wind speed and direction with height and can produce torrential rain, damaging hail, swirling winds, and sometimes tornadoes. Storm watchers are seen studying, imaging, and ultimately running from the developing storm cloud during the video. During the middle part of the video, the kilometer-wide supercell can be seen swirling ominously with a nearly flat bottom. Toward the end of the video, another swirling supercell cloud forms but then quickly dissipates.

Hubble's Jupiter and the Amazing Shrinking Great Red Spot 
Credit: 
NASA, ESA, and Amy Simon (Goddard Space Flight Center) et al.
Explanation: Gas giant Jupiter is the solar system's largest world with about 320 times the mass of planet Earth. It's also known for a giant swirling storm system, the Great Red Spot, featured in this sharp Hubble image from April 21. Nestled between Jupiter-girdling cloud bands, the Great Red Spot itself could still easily swallow Earth, but lately it has been shrinking. The most recent Hubble observations measure the spot to be about 10,250 miles (16,500 kilometers) across. That's the smallest ever measured by Hubble and particularly dramatic when compared to 14,500 miles measured by the Voyager 1 and 2 flybys in 1979, and historic telescopic observations from the 1800s indicating a width of about 25,500 miles on its long axis. Current indications are that the rate of shrinking is increasing for the long-lived Great Red Spot.

WR 104: A Pinwheel Star System 
Image Credit & Copyright: 
P. Tuthill (U. Sydney) & J. Monnier (U. Michigan), Keck Obs., ARC, NSF
Explanation: Might this giant pinwheel one-day destroy us? Probably not, but investigation of the unusual star system Wolf-Rayet 104 has turned up an unexpected threat. The unusual pinwheel pattern has been found to be created by energetic winds of gas and dust that are expelled and intertwine as two massive stars orbit each other. One system component is a Wolf-Rayet star, a tumultuous orb in the last stage of evolution before it explodes in a supernova -- an event possible anytime in the next million years. Research into the spiral pattern of the emitted dust, however, indicates the we are looking nearly straight down the spin axis of the system -- possibly the same axis along which a powerful jet would emerge were the supernova accompanied by a gamma-ray burst. Now the WR 104 supernova itself will likely be an impressive but harmless spectacle. Conversely, were Earth really near the center of the powerful GRB beam, even the explosion's 8,000 light year distance might not be far enough to protect us. Currently, neither WR 104 nor GRB beams are understood well enough to know the real level of danger.

Satellite Station and Southern Skies 
Image Credit & 
Copyright: James Garlick
Explanation: This clear night skyscape captures the colorful glow of aurora australis, the southern lights, just outside the port city of Hobart, Tasmania, Australia, planet Earth. As if staring into the dreamlike scene, the Tasmanian Earth Resources Satellite Station poses in the center, illuminated by nearby city lights. Used to receive data from spacebased Earth observing instruments, including NASA's MODIS and SeaWiFS, the station was decommissioned in 2011 and dismantled only recently, shortly after the picture was taken on April 30. Still shining in southern skies though, the central bulge of our Milky Way galaxy and two bright satellite galaxies the Large and Small Magellanic Clouds appear in the frame. The Small Magellanic Cloud shines through the fainter red auroral band.

Opportunity's Mars Analemma 
Image Credit: 
NASA/JPL/Cornell/ASU/TAMU
Explanation: Staring up into the martian sky, the Opportunity rover captured an image at 11:02 AM local mean time nearly every 3rd sol, or martian day, for 1 martian year. Of course, the result is this martian analemma, a curve tracing the Sun's motion through the sky in the course of a year (668 sols) on the Red Planet. Spanning Earth dates from July, 16, 2006 to June 2, 2008 the images are shown composited in this zenith-centered, fisheye projection. North is at the top surrounded by a panoramic sky and landscape made in late 2007 from inside Victoria crater. The tinted martian sky is blacked out around the analemma images to clearly show the Sun's positions. Unlike Earth's figure-8-shaped analemma, Mars' analemma is pear-shaped, because of its similar axial tilt but more elliptical orbit. When Mars is farther from the Sun, the Sun progresses slowly in the martian sky creating the pointy top of the curve. When close to the Sun and moving quickly, the apparent solar motion is stretched into the rounded bottom. For several sols some of the frames are missing due to rover operations and dust storms.

Halo of the Cat's Eye 
Image Credit & Copyright: R. Corradi (
Isaac Newton Group), Nordic Optical Telescope
Explanation: The Cat's Eye Nebula (NGC 6543) is one of the best known planetary nebulae in the sky. Its haunting symmetries are seen in the very central region of this stunning false-color picture, processed to reveal the enormous but extremely faint halo of gaseous material, over three light-years across, which surrounds the brighter, familiar planetary nebula. Made with data from the Nordic Optical Telescope in the Canary Islands, the composite picture shows extended emission from the nebula. Planetary nebulae have long been appreciated as a final phase in the life of a sun-like star. Only much more recently however, have some planetaries been found to have halos like this one, likely formed of material shrugged off during earlier active episodes in the star's evolution. While the planetary nebula phase is thought to last for around 10,000 years, astronomers estimate the age of the outer filamentary portions of this halo to be 50,000 to 90,000 years.


Astronomy News:

First light for SPHERE exoplanet imager

 

This infrared image shows the dust ring around the nearby star HR 4796A in the southern constellation of Centaurus. It was one of the first produced by the SPHERE instrument soon after it was installed on ESO's Very Large Telescope in May 2014 It shows not only the ring itself with great clarity, but also reveals the power of SPHERE to reduce the glare from the very bright star -- the key to finding and studying exoplanets in future. Credit: ESO/J.-L. Beuzit et al./SPHERE Consortium

SPHERE—the Spectro-Polarimetric High-contrast Exoplanet REsearch instrument—has been installed on ESO's Very Large Telescope at the Paranal Observatory in Chile. This powerful facility for studying exoplanets uses multiple advanced techniques in combination. It offers dramatically better performance than existing instruments and has produced impressive views of dust discs around nearby stars and other targets during the very first days of observations. It is expected to revolutionize the study of exoplanets and circumstellar discs. Included is one of the best images so far of the ring of dust around the nearby star HR 4796A.

SPHERE passed its acceptance tests in Europe in December 2013 and was then shipped to Paranal. The delicate reassembly was completed in May 2014 and the instrument is now mounted on VLT Unit Telescope 3. SPHERE is the latest of the second generation of instruments for the VLT (the first three were X-shooter, KMOS and MUSE).

SPHERE combines several advanced techniques to give the highest contrast ever reached for direct planetary imaging—far beyond what could be achieved with NACO, which took the first ever direct image of an exoplanet. To reach its impressive performance SPHERE required early development of novel technologies, in particular in the area of adaptive optics, special detectors and coronagraph components.
"SPHERE is a very complex instrument. Thanks to the hard work of the many people who were involved in its design, construction and installation it has already exceeded our expectations. Wonderful!" says Jean-Luc Beuzit, of the Institut de Planétologie et d'Astrophysique de Grenoble, France and Principal Investigator of SPHERE.

SPHERE's main goal is to find and characterise giant exoplanets orbiting nearby stars by direct imaging. This is an extremely challenging task as such planets are both very close to their parent stars in the sky and also very much fainter. In a normal image, even in the best conditions, the light from the star totally swamps the weak glow from the planet. The whole design of SPHERE is therefore focused on reaching the highest contrast possible in a tiny patch of sky around the dazzling star.

The first of three novel techniques exploited by SPHERE is extreme adaptive optics to correct for the effects of the Earth's atmosphere so that images are sharper and the contrast of the exoplanet increased. Secondly, a coronagraph is used to block out the light from the star and increase the contrast still further. Finally, a technique called differential imaging is applied that exploits differences between planetary and stellar light in terms of its colour or polarisation—and these subtle differences can also be exploited to reveal a currently invisible exoplanet.

SPHERE was designed and built by the following institutes: Institut de Planétologie et d'Astrophysique de Grenoble; Max-Planck-Institut für Astronomie in Heidelberg; Laboratoire d'Astrophysique de Marseille; Laboratoire d'Etudes Spatiales et d'Instrumentation en Astrophysique de l'Observatoire de Paris; Laboratoire Lagrange in Nice; ONERA; Observatoire de Genève; Italian National Institute for Astrophysics coordinated by the Osservatorio Astronomico di Padova; Institute for Astronomy, ETH Zurich; Astronomical Institute of the University of Amsterdam; Netherlands Research School for Astronomy (NOVA-ASTRON) and ESO.

During the first light observations several test targets were observed using the many different modes of SPHERE. These include one of the best images so far of the ring of dust around the nearby star HR 4796A. It not only shows the ring with exceptional clarity but also illustrates how well SPHERE can suppress the glare of the bright star at the centre of the picture.

Following further extensive tests and science verification observations SPHERE will be made available to the astronomical community later in 2014.

"This is just the beginning. SPHERE is a uniquely powerful tool andwill doubtless reveal many exciting surprises in the years to come," concludes Jean-Luc Beuzit.

Provided by ESO search and more info

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/ 



6 June
7:30PM
SBAS Monthly General Meeting
Topic: The Sounds of the Universe: Acoustic Astronomy 25 Years Later
Speaker: Dr. Fiorella Terenzi, Florida International University

9 June
Griffith Observatory
Event Horizon Theater
8:00 PM to 10:00 PM


19 June 2014
Club Meeting
 "Zooming into the center of our Galaxy: Of Black Holes and Gas Clouds".
Leo Meyer, UCLA
A1/1735
June 19 & 20  The von Kármán Lecture Series: 2014
Europa: The Challenges of Exploring a Cold, Distant World
Europa is one of the best targets in the solar system for finding existing life. Strong evidence from NASA’s Galileo spacecraft suggests that Jupiter’s moon Europa has a very large ocean of liquid salty water in contact with the icy outer crust. Atomic particles trapped in Jupiter's powerful magnetic field crash into Europa's icy surface with great energy, producing chemical compounds that could be used by living things. Europa's seafloor could be heated by the moon's constant flexing, driving hydrothermal activity similar to undersea volcanoes in Earth's oceans. This world has piqued the curiosity of scientists, who are trying to figure out how best to visit Europa and what kind of technology would be required to explore it.
Speaker:
Kevin Hand, Deputy Chief Scientist for Solar System Exploration

Locations:
Thursday, June 19, 2014, 7pm
The von Kármán Auditorium
at JPL
4800 Oak Grove Drive
Pasadena, CA
› Directions

Friday, June 20, 2014, 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.





Observing:
The following data are from the 2014 Observer’s Handbook, and Sky & Telescope’s 2014 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 June:


Moon: June 5 1st quarter, June 13 full, June 19 last quarter, June 27 new             
Planets:  Mercury is visible shortly after sunset.  Venus is visible just before dawnJupiter is up for a couple hours after sunset.  Saturn is up from sunset to early morning, and Mars from sunset to early morning.

Other Events:
3 June Double & triple shadow transits (Jupiter)

7 June
Public  Star Party: Griffith Observatory Grounds 2-10pm

8 June Mars 1.6deg N of Moon

10 June Saturn 0.6deg N of Moon, occultation & double shadow transit (Jupiter)

June 21 Solstice
 
21 June

SBAS Saturday Night In Town Dark Sky Observing Session at Ridgecrest Middle School– 28915 North Bay Rd. RPV, Weather Permitting: Please contact Greg Benecke to confirm that the gate will be opened! http://www.sbastro.net/

24 June Venus 1.3deg N of Moon

28 June
SBAS out-of-town observing – contact Greg Benecke http://www.sbastro.net/.  
28 June
LAAS Dark Sky Night : Lockwood Valley (Steve Kufeld Astronomical Site; LAAS members and their guests only)

Internet Links:

Link(s) of the Month

A weekly 5 minute video about what’s up in the night sky:  www.skyandtelescope.com/skyweek.

Telescope, Binocular & Accessory Buying Guides


General


Regional (Southern California, Washington, D.C. & Colorado)


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/

 
Membership.  For information, current dues & application, contact Alan Olson, or see the club website (or Aerolink folder) where a form is also available (go to the membership link/folder & look at the bottom).  Benefits will include use of club telescope(s) & library/software, membership in The Astronomical League, 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:  Mark Clayson, President & Program Committee Chairman (& acting club VP), TBD Activities Committee Chairman (& club Secretary), or Alan Olson, Resource Committee Chairman (over equipment & library, and club Treasurer).

Mark Clayson,
AEA Astronomy Club President 

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