6.10.10
Stars Shine on East Gainesville
As part of an ongoing effort to reach out to the community, the University of Florida Music and Arts for Science Outreach Initiative in the Department of Astronomy is hosting “Stars Shine on East Gainesville,” a celebration of art, science and culture, from 6:30 - 9:30 p.m. Friday October 8 at the Martin Luther King Center (1028 NE 14th St). The event is free and open to the public.
Participants will be able to view the night sky with telescopes, participate in art projects, and learn about the ASTREC small satellite project. Pizza and soda will be available for purchase. Other events include:
6:30 pm at the Northeast Pool: Gainesville Gaviatas Synchronized Swimming will present The Art & Science of Conservation of Motion
Following at the MLK Center:
Jorge Variego, Music From Space: Black holes, Planets, Light Waves
Performance by the Howard Bishop Symphonic Winds
Astro Art Exhibit from the East Gainesville Initiative Summer Camp Students and award ceremony with Dr Jaydeep Mukherjee.
NASA Hands on activities outreach group from Kennedy Space Center.
Sponsored by: The National Science Foundation through a grant to Stephen Eikenberry and Reba Bandyopadhyay in the Department of Astronomy; NASA Florida Space Grant Consortium, University of Florida Music and Arts for Science, ASTREC, Gainesville Gaviatas, UF School of Music: College of Fine Arts, and Cotton Club. Partnering With: Santa Fe College East Gainesville Initiative, and the Alachua Astronomy Club.
4.10.10
CanariCam Passes First Tests
Take one of the world's most complicated instruments, a 400 ton behemoth telescope, and marry it to a high tech sophisticated and sensitive mid-infrared (MIR) camera, and you know you have quite a challenge in front of you. That's what happened over the past two weeks on top of the Roque de los Muchachos observatory site in La Palma, Canary Islands. The University of Florida's MIR CanariCam was powered up and placed on the Nasmyth focus of the 10.4 GTC segmented mirror telescope.
But before commissioning of the new CanariCam instrument could begin, the weather had to cooperate - and it didn't. Three days of clouds, wind and torrential rains assaulted the peak, making any useful testing impossible. After that, the lingering humidity continued to pose a problem for the telescopic optics and seeing.
Finally Monday night, September 27, with just three nights left on the observing run set aside for CanariCam, the weather and humidity cooperated with clear skies. Star images through the GTC were somewhat degraded, but with some manipulation, pinpoint imaging was obtained and CanariCam began taking images on the sky. Much to the satisfaction of the GTC observing staff and Florida team members, CanariCam began performing very close to the diffraction limit of the telescope. For a 10.4 meter telescope operating in the mid-infrared (0.2 arc second angular resolution at 10 micron MIR range), that's saying a lot!
Because light acts as a wave, any attempt to resolve very small images will be limited by the size of the instrument being used. The larger the aperture of the telescope, the better the resolution. That's the common sense reason why bigger telescopes see more than backyard scopes. CanariCam can take this size advantage of the GTC and operate very near its diffraction limit because the longer specific wavelengths of the mid-infrared reduce distortions caused by the atmosphere. As the accompanying photo shows, stellar images are indeed resolved near the diffraction limits of the GTC.
But operating in the mid-infrared range also produces extra demands on the telescope. "Chopping and nodding" is the process previously described of introducing small offsets in multiple images to reduce extraneous radiation and allow a better view of the astronomical target. This requires, however, that the GTC subsystems must perform these minor adjustments flawlessly, especially the GTC secondary mirror which must move tiny fractions of space in very small increments of time.
Large structure holding secondary mirror of GTC, required to oscillate up to 10 arc seconds several times a second
When the commissioning testing attempted to introduce chopping and nodding to the mix, problems were encountered, especially when combined with the tracking and guiding needs of the observations. Throughout the first full night of observations, various faults kept cropping up, making useful commissioning tests impossible. Still, learning that CanariCam can operate at or near the diffraction limit was an important milestone.
The two remaining nights available for commissioning were likewise frustrating. High humidity, combined with various fault warnings with the telescope's operation, resulted in the inability to test CanariCam on any more "interesting" objects.
Throughout the operation, the GTC engineering and science staff worked closely at all times with the Florida team, demonstrating obviously intense commitment to the overall scientific project. Principal Investigator Charlie Telesco believes that, given the logistics of getting to and from the Canary Island site, the real possibility exists of finding more ways to use remote access between the teams (video link and internet link) so that effective coordination might allow the GTC staff to carry out many of the commissioning activities with "real time" help from the Florida team. For example, most of the GTC problems encountered so far appear to be software issues, which Senior Software Engineer Frank Varosi may be able to assist with long distance.
GTC staff astronomers and University of Florida team members in control room
Meanwhile, what about that pesky coldhead that caused such anxiety during the initial stages? Even though the detector had to be powered off a few times to accommodate telescope adjustments, it basically maintained temperatures in the 8.74K to 8.76K range, good enough for getting useful data. Putting a newer one on will improve on this, but the old coldhead has been a true workhorse during the frustrating final days. Meanwhile, CanariCam is still cold and remains on the telescope, making continued commissioning over the next several weeks a real possibility.
So final commissioning of CanariCam will have to wait, but its performance to date is extremely promising. Once the "prenuptial agreements" between it and the GTC have been worked out, a successful marriage appears to be in the works. Congratulations are due to the entire Florida team and the hardworking staff at GTC. CanariCam and the GTC will soon be combining their resources to discover new secrets lurking behind obscuring clouds of interstellar dust.
CanariCam at GTC Nasmyth focus, waiting for clear skies
25.9.10
Coming down a mountain should be easier than going up, but not this time. The storm that assaulted the Roque de los Muchachos mountain top observatories, has rendered any observations impossible through the 10.4 meter GTC telescope. It also has triggered several rock slides along the narrow two-lane road that snakes its way up the side of the ancient volcano. Enormous boulders have completely closed off the road back to Santa Cruz de la Palma.
Two nights of heavy rain and and high winds have further delayed commissioning of the CanariCam. Everything has checked out so far, including the complicated software interfaces with the observatory’s system. All that is need are a few nights of clear skies so that the infrared camera’s performance can be verified. Then it can begin looking deeper into active galactic nuclei hiding supermassive black holes, and debris orbiting young stars in the process of forming their own planetary systems. Today, September 25, it looks like the skies are finally clearing over the island of La Palma.
CanariCam’s intricate optics and electronics are housed within a hexagonal black structure able to withstand the extreme pressure caused by the fact that, although its interior is at a near vacuum, 14.7 pounds per square inch of atmosphere is pressing in.
CanariCam in lab before installation
The interior is also maintained at a temperature of 8-10 Kelvin, just 14.4 degrees Fahrenheit above “absolute zero.” For this reason, astronomers often refer to the camera structure as the “dewar,” a device used for containing and maintaining extremely cold temperatures (essentially a very large and very efficient thermos).
Depending on the mode being used during infrared observations, the optical path from the main telescope may pass through a spectrograph, splitting the electromagnetic radiation and allowing examination of individual spectral lines created by the presence of different elements.
In the polarimetric mode, however, CanariCam can also detect the orientation of radiation that has been polarized through various physical processes. UF astronomer Jonathan Tan, for example, hopes to examine very young stars in the Orion Nebula (M42), a stellar nursery about 1350 light years from us. The stars which have just formed from a collapsing cloud of dust and gas are obscured in visible light by considerable dust, but CanariCam can pierce through and afford a better look. By seeing the actual orientation of this dust caused by enormous magnetic fields, we may be able to better understand the way in which stars and their associated protoplanetary disks form and develop over time.
Uf Astonomer Chris Packham adjusting polarimetric filter for CanariCam installation
CanariCam also has a coronagraph, which basically allows an obscuring disk to be placed in the optical path, allowing the high radiation from bright objects such as stars to be physically blocked out and prevented from overwhelming the fainter surrounding details. The coronagraphic and polarimetric capabilities of CanariCam are unique among the world's mid-infrared instruments.
Many projects are vying for time on CanariCam. Once the camera is successfully commissioned, the largest single telescope in the world will have a new window on the universe. The University of Florida instrument will be only the second one commissioned for this incredible telescope, explaining the keen interest and commitment of the observatory staff to help out every step of the way.
CanariCam installed at focus, with 42 inch GTC secondary mirror assembly visible in upper background
Meanwhile, a lot closer to home, due to the rock slides it is impossible to drive up or down the mountain without a relay of vehicles to assist. I hitched a ride part way down with some astronomers from Durham University in Northern England, who are working on experiments in adaptive optics with another telescope, This technique attempts to eliminate the effects of turbulence in the atmosphere by making minute observations of its effects and adjusting the shape of the telescope mirror in real time to compensate for such fluctuations.
Astronomy is a cooperative international endeavor. Through its partnership with the GTC and through its design and construction of instruments such as Professor Charles Telesco's CanariCam, and Professor Steve Eikenberry's FLAMINGOS-2 (a near-infrared wide field imager with multi-object spectrographic capabilities, installed at Gemini South Observatory, Chile), the University of Florida stands shoulder to shoulder with astronomers from around the world, putting Gators at the forefront of new scientific discoveries.
These blogs were written by Terry Smiljanich, a member of the Advisory Council of the UF Department of Astronomy, and will continue next week with updates on the continued commissioning and performance of CanariCam.
22.9.10
September 22, 2010
GTC Observatory
Roque de los Muchachos
La Palma, Canary Islands
All dressed up and no place to go! CanariCam, the University of Florida’s new high tech mid-infrared camera, is hooked up to the spectacular 10.4 meter (410 inch) GTC telescope, passing all of its commissioning tests so far with flying colors, and ready to start bringing in new astronomical data from deep space. But closer to home, a strong front has moved in and the mountaintop is covered in clouds, rain cascading off of the closed up dome, while the telescope sits idle, safely within its custom made garage.
The storm is bad enough that local authorities have activated emergency plans due to heavy rain and winds. On the mountain, movement is restricted between the astronomers' dormitory and the telescopes. If the weather continues to deteriorate, there is a possibility that the GTC telescope operator might decide to temporarily abandon the telescope. Here at the GTC, all is quiet and uncommonly empty as the rain continues to fall. Oh well, no scientific data today.
Into the early morning hours, the team has been checking out the workings of the University of Florida's CanariCam, designed and constructed by Professor Charlie Telesco and his team. They are making sure that it is properly aligned with the telescope, is communicating with the control room scientists, and is receiving images as expected. Until it clears up, however, the only “objects“ it can image are a couple of astronomers on the catwalk of the dome. The man on the right is doing the Gator chomp, imaged at mid-infrared!
Once the weather clears (maybe by Friday), the team can point to a few bright stars, check the pupil alignment, make sure the guiding of the telescope is working with the camera, and finish full commissioning of CanariCam. Then the real working science can begin.
Charles Telesco, Principal Investigator on CanariCam
Because the instrument must be able to pick out the relatively few photons from a distant protoplanetary disk or galactic nucleus, mixed in with millions of extraneous photons from the background radiation, the atmosphere, and the telescope itself, it is necessary to use a few astronomical tricks such as “chopping and nodding.”
Chopping is the process of offsetting the imaging by a tiny amount. Because the background radiation stays relatively the same for each offset image, they can be subtracted from the final image to eliminate the unwanted radiation from the final data. These offsets can be as small as 10 arc seconds (trust me, that’s a very tiny amount) every 5 seconds.
Nodding is the additional process of moving the telescope to a new nearby position once or twice a minute. This further refines the final image across the field of view, helping to eliminate the heat of the telescope itself. The combination of techniques allows CanariCam to detect faint objects with as little as a couple of minutes of exposure, and draw out the fine details that will reveal more knowledge of our universe.
All of this, of course, depends on the proper functioning of the telescope itself. A tour of the observatory with Chief of Operations Michiel van der Hoeven, originally from the Netherlands, reveals just how complicated this can be.
Michiel van der Hoeven, Chief of Operations, GTC
He explains that ventilation of the dome is critical. As any amateur astronomer can tell you, it does no good to have a large telescope and a clear night if your lenses are dripping with dew from the moist outdoor air. Also, air turbulence inside the huge dome can deteriorate the telescope’s performance.
An entire intricate system of cooling units (twenty large air conditioners), vents, and windows keep the interior of the dome cool and balanced so that when the dome is opened, the mirrors are at the proper temperature.
Moving a 400 ton telescope poses its own problems, but the GTC has that task well in hand. The entire telescope rests on hydrostatic bearings - not steel bearings, but rather a very thin layer of pressurized oil, which minutely lifts the telescope and allows it to glide with almost no friction. A child pushing against the telescope’s frame can move the entire assembly, giving a few visiting children bragging rights. “I moved a 400 ton telescope with my bare hands."
Closeup of bottom edge of telescope dome resting on pressurized oil, the overflow dripping into a pan
Although the GTC is functioning and busy with astronomical projects, aspects of its operation are still being worked on. The large ventilating windows on the dome, which will allow the flow of outdoor air to keep the telescope cool, are not fully operational as yet. Also, the dome doors do not fully open, limiting the telescope to a maximum elevation of about 70 degrees, plenty for important work but not yet 100%.
The 36 segmented mirrors are each separately controlled by motors mounted on their backsides. These allow fine adjustments to be made to their surfaces, sometimes as small as 2 nanometers (one billionth of an inch!), making sure the mirrors are in fact working as one large almost perfect mirror surface.
View of the rear of a spare segmented mirror
Alien asteroid belts and the secrets of our Milky Way's center must wait, however, as the rain continues to beat against the windows of the control room. Twenty astronomers and observatory staff were crowded in here just a few days ago, but now it contains only team member Frank Varosi, continually massaging the software interfaces and controls, a lone telescope operator, and me - an amateur astronomer having the experience of a lifetime.
Frank Varosi, Senior Software Engineer
Terry Smiljanich
21.9.10
"CanariCam Is In 'Da House"
Early in the morning, the control room of the Grantecan 10.4 meter telescope is filling up with excited observatory staff and astronomers. Michiel van der Hoeven, Chief of Operations at the world's largest telescope, convenes a meeting of 17 staff members plus the six members of the University of Florida team, to plan the complicated logistics of getting the CanariCam instrument and its associated electronic hardware from the laboratory up to the Nasmyth focus of the telescope. He has written "CanariCam is in 'da house!" on the message board.
Since the camera will be unhooked from its cooling unit during the transfer (and thus lose ground on maintaining a cold interior), it is imperative that the move be made as seamlessly as possible. Teams are assigned so that this can be accomplished in two hours, the length of time it took to do this last November when the camera was temporarily installed on Grantecan during "first light." "O.K.," Michiel announces, "let's rock and roll then."
A multitude of hoses, cables, interfaces, and connectors are disengaged from the camera and its cabinets, and everything is wheeled from the lab to the freight elevator to be lifted up to the telescope floor. Once there, a crane lifts CanariCam up to the platform where the telescope focus is located, and carefully bolted to the adaptor plate. Then the frame holding the electronic cabinets is hoisted and wrapped around the camera unit.
Now everything has to be reconnected, but the several staffers and Florida team quickly get matters in order, and the comforting thump of the coolhead can be heard, bringing the critical temperatures back down. One and a half hours - better than last time and a tribute to the efficiency of the Grantecan staff and the expertise of Greg Bennett, Florida's team engineer. Everyone is gratified that the camera has been successfully attached to Grantecan with minimal problems.
Watching this large group of men and women struggling to get everything performed to perfection, one is struck with awe at the fact that they are all working together, not to find more efficient killing machines or better ways of polluting our planet, but rather for the cause of pure science, expanding our knowledge of the universe we live in.
After lunch, a further group meeting plans the important task of making sure that CanariCam is perfectly aligned with the telescopic optics. This means opening the dome and moving the huge telescope during the afternoon.
In the control room, UF team members Frank Varosi and Chris Packham monitor the images coming in from the camera to evaluate the needed corrections, and communicate their findings to Charlie Telesco and Greg Bennett up at the telescope, who are making fine adjustments in the position of the camera housing at the telescope's focus.
When you are dealing with the need for sub-arc second accuracy in finding and capturing a few photons that have traveled thousands, millions and even billions of light years, you can appreciate how delicate such adjustments can get.
With the dome open during the day, and the telescope moving silently and smoothly into position, the sheer massiveness of the 10.4 meter telescope, together with its perfect balance in its mounting, can truly be appreciated.
CanariCam rests comfortably in its cradle, waiting for commissioning checkouts and a suitable target to demonstrate its powerful capabilities. Charlie Telesco and graduate student Dan Li proudly hang up a Gator banner in the control room, reminding everyone that the University of Florida is not just a 5% partner in the telescope, but also the creator of one of the first important astronomical instruments that will be used on Grantecan.
Terry Smiljanich
20.9.10
Getting CanariCam Ready, Day Four
GTC Observatory
Roque de los Muchachos
La Palma, Canary Islands
Overnight, the hard working compressor finally got the temperature of the infrared detector down to where it needs to be, about 444 degrees below zero. A meeting is held in the morning with the observatory staff to coordinate the many activities that need to occur, some simultaneously, to get CanariCam ready for use on the GTC (Grantecan) telescope. Michiel van der Hoeven, Chief of Operations at the observatory, tells us that the staff stands ready to help get the instrument commissioned.
Now a new enemy is raising its ugly head - bad weather, the bane of every astronomer's existence. A storm is predicted to come through Wednesday, just when it is hoped that the University of Florida team can begin making initial observations. Nothing to do about that but wait and see. Astronomers tell stories of waiting months to get one precious night on a large telescope for a project, only to have that be the one night when it decides to rain, ruining the observations and requiring another multi-month wait for another try.
The observatory staff is already putting on the adaptor plate on the telescope, which will allow CanariCam to be fitted to the telescope's focus. The thick black steel plate, specially designed for CanariCam, weighs over a ton and takes three workers and a crane to get it up to the focus and bolted to the telescope. The segmented mirror (36 separate mirrors), largest in the world, sits on its side in the dome, waiting to be let loose on the skies.
In a room under the dome, six extra mirrors are kept in storage, ready to act as replacements as needed. UF astronomer Chris Packham gives us an up close look at these individual mirrors. Their undersides are covered with intricate motors and pulleys which can slightly bend the shapes of the mirror surfaces, compensating for minor errors and seeing conditions.
Suddenly, at about 12:30, the steady drone of the compressor ceases and everything gets strangely quiet in the lab. The compressor has quit working and the internal temperatures are starting to climb back up. Everyone stops what they're doing, and an intense session of troubleshooting begins. Gregg Bennett, the team engineer, takes the cover off. The compressor tank has overheated. A short? A bad solenoid switch? A helium leak? A replacement compressor is wheeled in, but the detector temperature is already back up to minus 425 degrees F, extremely cold but much too hot for infrared work. A few tweaks later and the old compressor kicks back on. The temperature immediately drops back down to comfortable levels.
Except for the activities of the CanariCam team and staff, the cavernous dome is empty and quiet. One floor below, the control room mainly consists of a maze of computer screens. Here, the dome can be opened and rotated, and the telescope pointed with extreme accuracy. Some of the more precise guiding aspects of the telescope are still being modified, but it is hoped that both the telescope and CanariCam will soon demonstrate that they make a fine pair. That is, if the weather holds up!
Terry Smiljanich
19.9.10
CanariCam Cooldown, Day Three
Roque de los Muchachos Observatory
La Palma, Canary Islands
Minus 340 degrees Fahrenheit and counting. The cryogenic pump has been working for over 55 hours hours now as the temperatures inside CanariCam slowly decline to optimal levels (10K or less at the critical detector and we’re OK). Meanwhile, the vacuum inside CanariCam is being maintained at levels equal to about one ten billionth of the air pressure at sea level.
Observatory staffers ask how it’s coming, as everyone is anticipating mating the CanariCam mid-infrared camera with the 10.4 meter Grantecan telescope. With the gathering power of the huge mirror (composed of 36 separate mirrors all working together as one large mirror), and the sensitivity of the University of Florida instrument, new astronomical discoveries are potentially around the corner.
There is a small “window” in our atmosphere at 10 microns (infrared wavelengths one hundredth of a millimeter in length) where electromagnetic radiation can pierce through the water vapor that blocks most of the infrared. CanariCam’s detector can observe through this window, and with the power of Grantecan will hopefully be able to achieve an angular resolution of up to 0.20 arc seconds. For us non-astronomers, that’s equivalent to being able to see the width of a human hair held 500 feet away). It is thus possible that with CanariCam we may better understand how planetary systems such as our own solar system develop over time.
Perhaps CanariCam will resolve the debris disk surrounding a faint planetary system with sufficient detail to determine whether it includes an asteroid belt similar to our own. If so, we can better understand planetary systems as a whole, rather than just the individual planets that are being discovered on a monthly basis.
This is just one of many projects proposed for CanariCam once it is commissioned. Another proposal, by UF astronomer Jonathan Tan, wants to look at very young stars buried in the dust of the Orion Nebula. CanariCam has unique polarimetric capabilities, allowing an observer to sort out the distribution of magnetic fields as they create polarization in dust particles surrounding a star. With this new tool, the development of protoplanetary disks over time can begin to be mapped out and compared to theoretical predictions.
All of this is a part of the busy astronomical activity going on at the top of this mountain. Practically next door, the 4.2 meter (163 inches) William Herschel Telescope, built in 1987, was at one time the third largest telescope in the world, before being eclipsed by the new generation of 8-10 meter telescopes like Gemini, Keck, and Grantecan. The Herschel was the first to provide evidence of a supermassive black hole, called Sagittarius A, at the center of our own Milky Way galaxy. The Deputy PI on CanariCam, University of Florida's Chris Packham (Charlie Telesco is the Principal Investigator, as Chris hastens to add), once worked with the Herschel, and proudly gave us a tour of this venerable telescope.
The MAGIC I & II instrument, just down slope from Grantecan, consists of twin 17 meter segmented mirrors pointed horizontally and looking for lingering evidence of gamma rays striking the atmosphere that came from supernovae and accretion disks around supermassive black holes. These black holes, from which no light can escape, have incredible masses, from 4 million suns to billions of suns, all crammed within very small spaces very far away. They remain invisible, but the havoc created by their interaction with surrounding matter creates super-energetic rays that can be detected. This June MAGIC detected cosmic rays from a quasar 6 billion light years away. When these rays left their source, our own Sun had not even been born yet).
All the CanariCam team can do today, a quiet Sunday with clear blue skies, is wait and watch the slopes of the cooling curves. Once the proper temperatures are reached, however, organized chaos will descend as everyone runs through final checks and the large instrument is lifted up to the observing platform and the telescope silently moves toward a distant target. You can already sense the excitement that will run high in the control room adjacent to the telescope when that happens.
Terry Smiljanich
18.9.10
At the Gran Telescopio Canarias, Day Two
With a few clouds drifting through the collection of white domes at the top of the Roque de los Muchachos peak, we drive up to the Grantecan to see how the cooldown is progressing. Working our way through some tourists visiting the world’s largest telescope, we head for the laboratory, where all through the night the refrigerant pump has been using helium to bring the internal temperature of the CanariCam infrared detector closer to the working target of approximately 8K.
The temperature detectors, monitored through software designed by team member Frank Varosi, show the steady progress of cooling down. The detectors are currently showing temperatures as low as 40K (-388 degrees Fahrenheit), slowly dropping after 25 hours of pumping.
Cold yes, but not nearly cold enough to allow the detector to find and count the few feeble photons making their way to Earth from cold debris surrounding a star 63 light years away, or sneaking through dust surrounding the center of our own Milky Way some 26,000 light years distant. Greg Bennett, the team engineer, adjusts a relief valve, watching the pressure readings, and the pump quietly whines away as the temperature slowly creeps downward.
The air is cool and dry at 7900 feet. Spectacular sunsets are routine here above the clouds. Due to its location, this peak is one of two premier observing sites in the Northern Hemisphere (the other being Mauna Kea in the Hawaiian Islands). The island, La Palma, is the most northeasterly of the Canary Islands, just a few hundred miles from the Moroccan coast of Africa.
The peak, called Roque de los Muchachos, is named after an outcropping of volcanic rocks looking somewhat like tall humans. It perches on the very rim of a huge caldera formed from the collapse of the Taburiente volcano a half million years ago. The caldera is six miles across and almost as deep as the Grand Canyon. From the top, at sunset one can see the shadow of the mountain cast across the Atlantic Ocean, with the island of Tenerife clearly visible.
It is here that the European Northern Observatory operates thirteen world class telescopes, with teams from Great Britain, Italy, Spain, the United States, and other countries, all working on scientific projects to explore the farthest reaches of space and time. In addition to Grantecan, other famous telescopes abound, such as the William Herschel Telescope (4.2 meters), the TNG (Galileo), and “MAGIC,” a twin set of huge 56 foot mirrors pointed horizontally and looking for particle showers caused by cosmic rays.
The University of Florida is a 5% partner in the Grantecan telescope, inaugurated in 2009, and is designing and utilizing instruments such as CanariCam for use on the facility. In return, the Florida team has access to the telescope for its own projects. Because the target is to commission CanariCam on the telescope next week at the Nasmyth focus (one of the observing spots on the telescope), the Florida team has exclusive access to the telescope for a few nights, both to commission the instrument and begin collecting important scientific data. One can detect the envy in the voices of other astronomers during mealtime discussions. “Ah, you're on the Florida team. You have the Nasmyth focus next week!”
17.9.10
CanariCam Commisioning at the GTC
September 18, 2010, La Palma, Canary Islands
An ocean away, on top of a tall mountain overlooking the Atlantic and the clouds far below, we finally arrive at the world’s largest telescope, the Gran Telescopio Canarias (Grantecan). The University of Florida team, led by Professor Charles Telesco, is here to officially commission its new mid-infrared camera, the CanariCam, specially designed to work in conjunction with Grantecan to explore regions of space normally inaccessible to visible light.
Internationally known for its expertise in designing, building and using high end astronomical instrumentation on some of the world’s largest telescopes, the University of Florida will install CanariCam on the business end of the 500 ton telescope facility, which uses a segmented mirror 34 feet across (over twice as large as the iconic Mt. Palomar 200 inch telescope in California). With what amounts to the largest eye on the planet, the heat sensitive CanariCam will be able to peer through obscuring interstellar dust with unprecedented accuracy, looking, for example, at the center of galaxies hiding black holes, or looking for exoplanets (planets outside our own solar system) in the process of forming around young stars.
First,however,the complicated instrument, as large as a coffee table, and hooked to closet-sized electronic cabinets, has to be checked out to make sure it is ready for installation and use. And that can get hairy. In order, for example, for the camera to detect the extremely faint emissions from distant heat sources, it has to eliminate as much as possible the heat being generated closer to home, the camera housing itself and the very telescope it is using. In addition, it has to peer through the heavy humid atmosphere of Earth.
In order to accomplish this, the infrared detector at the heart of the camera must be cooled to around 8 Kelvin (that’s -445 degrees Fahrenheit). But the new two stage cryogenic “coldhead,” which allows it to achieve such frigid temperatures, is giving the team fits. Switching back to an older coldhead unit, everyone is anxiously watching the monitors as the slow process of cooldown is underway. The laborious process should be completed by Sunday, at which time the instrument can be checked out and, if everything goes well, readied for installation on the telescope.
Astronomers from around the world are waiting, their proposals for using the unique instrument dependent upon a successful commissioning. These proposals include new examinations of protoplanetary and debris disks around young stars (potentially letting us observe the formation of new planetary systems), and penetrating the interior of active galactic nuclei, obscured by dust in the visible spectrum.
For an amateur astronomer like me, living temporarily in an astronomical community and working in a laboratory sitting beneath such a magnificent telescope, I keep waiting for someone to wake me up. “What are you doing here?” I hope to document this exciting activity in pictures and in this blog, hopefully giving a sense of being amidst science at the cutting edge. Each day for the next week I will post observations and photos, following the progress of the Florida team, explaining infrared astronomy in further detail, and looking more closely at the capabilities of CanariCam.
Terry Smiljanich
13.9.10
Rosemary Reborn: Students Upgrade the 30" Telescope at Rosemary Hill Observatory
4.6.10
UF Astronomy professor is invited speaker at American Astronomical Society meeting in Miami
13.5.10
University of Florida Astronomer Calls on Congress to Support Investments in Research and Development
Reba Bandyopadhyay, Assistant Scientist at the University of Florida, traveled to Washington, DC, to express thanks and appreciation to Congress for recent appropriations actions in the FY2010 spending bill in support of science, engineering, and technology research and development (R&D).
Dr. Bandyopadhyay joined with more than 250 scientists, engineers, and business leaders who made visits on Capitol Hill as part of the 15th annual Congressional Visits Day, sponsored by the Science-Engineering-Technology Work Group (www.setcvd.org), on April 28-29. She was one of 16 members of the American Astronomical Society (AAS) who traveled to Washington for the event.
While visiting congressional offices, CVD participants discussed the importance of the nation’s broad portfolio of investments in science, engineering, and technology to promoting U.S. prosperity and innovation. Most importantly, they provided a constituent perspective on the local and national impact of these programs and their significance to Florida. Dr. Bandyopadhyay visited the offices of Senators Bill Nelson and George LeMieux and Representatives Corrine Brown and Cliff Stearns, speaking to staffers for each Congressperson about the importance of federal funding for science R&D. She spoke specifically about ground- and space-based astronomical instrumentation development currently underway at UF, and how such work can help to build Florida’s “knowledge economy”.
“I was very pleased to participate in Congressional Visits Day. I believe that discussing the benefits of federal science and technology programs in person with our elected legislators is critical to securing the ongoing support of agencies such as NSF and NASA. The technology arising from the research in these federal agencies is central America’s competitiveness in the world economy.”
More than 50% of all industrial innovation and growth in the United States since World War II can be attributed to advances pioneered through scientific research, with publicly funded R&D the vital foundation for today’s scientific and technological progress. Achievements from federally funded science, engineering, and technology include global environmental monitoring, lasers, liquid crystal displays, the Internet, and many other scientific and technical advances.
The federal government supports a unique research and education enterprise that fuels the American economy. This enterprise provides the underpinning of high-technology industries and expands the frontiers of knowledge in every field of science. Much of this research is carried out at academic institutions across the country, ensuring knowledge transfer to future generations of scientists, engineers, mathematicians, physicians, and teachers. Additionally, technology transfer from academic research adds billions of dollars to the economy each year and supports tens of thousands of jobs.
Dr. Bandyopadhyay said that her most memorable experience was visiting the offices of Florida’s two Senators. “I was impressed with the interest in and knowledge about science and technology research shown by the staff members of both Senators Nelson and LeMieux. They clearly understood the importance of R&D to Florida, and how federal funding is vital to such research in our public universities and NASA.”
More information about 2010 Congressional Visits Day can be found at on the Web: http://www.setcvd.org
12.5.10
Astronomers plan second look at mega star birthing grounds
Astronomers this summer will take a close look at a rare cosmic cradle for the universe’s largest stars, baby bruisers that grow up to have 50 times the sun’s mass.
The international team of astronomers headed by University of Florida scientist Peter Barnes used an Australian radio telescope to find the cloud of gas and dust 8,000 light years away in the Southern sky constellation Carina. The cloud is in the early stages of collapsing in on itself, offering astronomers an unusual vista on the first contractions of behemoth star birth.
“We understand some of it, but we really don’t have a clear picture of what’s important,” Barnes said. “This should help us learn a lot more about the process.”
Although our sun has far less mass than the incipient stars in the gas cloud, studying their formation could help astronomers understand how our solar system formed, Barnes said. That is because many stars the size of our sun are thought to have formed in clusters that dispersed into space over millions of years. It’s possible, Barnes said, that our sun traces its origin to such a cluster, and in fact chemical anomalies on meteorites suggest that’s the case.
The latest findings, which appeared in the monthly journal Notices of the Royal Astronomical Society, have spurred the team to plan a closer look with another Australian telescope in August. The team will also use the Gemini South telescope, equipped with a mid-infrared camera designed and built at UF, to observe the cloud from the telescope’s location in Chile.
Stars at least 10 times the mass of our sun are rare, comprising only about 4 percent of those in the universe. Most are also at least 1,000 light years away and hard to study. It’s exceptionally rare for astronomers to encounter clouds of gas and dust early in the process of collapsing into large stars because the stars tend to destroy their natal origins.
“They’re rather nasty tykes,” Barnes said. “They make a big mess.”
The astronomers discovered the gas cloud as part of a survey of 300 large gas clouds using the Australia Telescope National Facility’s 22-meter Mopra radio telescope in southeastern Australia. The telescope’s world-class spectrometer allows astronomers to identify and image carbon monoxide and other molecules in large gas clouds. Even with that technology, the mega star birthing cloud was the only one of its kind among the 300 surveyed.
The cloud is also unusual in its rapid pace of collapse and the amount of dust and gas, an amount so large it eclipsed the large stars that had already coalesced inside the cloud. “It is a few light years across, and it has maybe 20,000 times the sun’s mass worth of gas and dust, and most of that is participating in the collapse,” Barnes said.
5.5.10
The Formation of Stars
Stars to Galaxies Conference
15.4.10
Shuttle Launch
31.3.10
Life in the Universe
image credit: Undergraduate Astronomy Association
25.3.10
Our Cosmic History: From Big Bang to Big Molecules
image credit: Jonathan Tan
22.3.10
What do astronomers do?
What do astronomers do? is an educational flash animation that mixes video interviews, imagery, and typography in order to demystify the image of the astronomer and bringing it closer to a broad audience.
For his purpose, Jorge had the pleasure to interview several members of our department, including our Chair, Rafael Guzmán, and our Associate Chair, Ata Sarajedini. The interviews also included professors Vicki Sarajedini and Eric Ford, doctorates Ashley Espy and Bruno Ferreira, and graduate students Scott Fleming, Nestor Lasso, Enrique López, Jesús Martínez, Robert Morehead, and Izaskun San Roman. Also, both Rafael Guzmán and María Rogal, a professor and Jorge's adviser at the School of Art and Art History, helped him with the final polishing of his work.
Furthermore, the included high definition video interviews are now available through our youtube channel.
astronomers
do? by jorge pérez-gallego
Answers to the question you have been always wondering about..
19.3.10
Redesign
Along with this release comes this blog, aimed to keep our followers up to date on everything related to the professional endeavors of our department and its members, with news, announcements, and stories that will please everyone with an interest in astronomy in general, and our department in particular.
Stay tuned for many more things to come in the near future.