Combined Array for Research in Millimeter-wave Astronomy

Combined Array for Research in Millimeter-wave Astronomy

Alternative names	CARMA
Part of	Owens Valley Radio Observatory
Location(s)	California, Pacific States Region
Coordinates	37°16′49″N 118°08′31″W / 37.2804°N 118.142°W / 37.2804; -118.142
Organization	California Institute of Technology
Altitude	2,196 m (7,205 ft)
First light	2005
Telescope style	radio interferometer
Website	www.mmarray.org
Location of Combined Array for Research in Millimeter-wave Astronomy
Related media on Commons
[edit on Wikidata]

The Combined Array for Research in Millimeter-wave Astronomy (CARMA) was an astronomical instrument comprising 23 radio telescopes, dedicated in 2006.^[1] These telescopes formed an astronomical interferometer where all the signals are combined in a purpose-built computer (a correlator) to produce high-resolution astronomical images.^[2] The telescopes ceased operation in April 2015 and were relocated to the Owens Valley Radio Observatory for storage.

The Atacama Large Millimeter Array in Chile has succeeded CARMA as the most powerful millimeter wave interferometer in the world.^{[citation needed]}

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Today's telescopes study the sky across the electromagnetic spectrum. Each part of the spectrum tells us different things about the Universe, giving us more pieces of the cosmic jigsaw puzzle. The most powerful telescopes on the ground and in space have joined forces over the last decade in a unique observing campaign, known as GOODS, which reaches across the spectrum and deep back into cosmic time. This is the Hubblecast. News and images from the NASA/ESA Hubble Space Telescope, travelling through time and space with our host Dr J, aka Dr Joe Liske. Hello and welcome to this very special “multicast”. We’ll be exploring a unique collaboration between some of the world’s most powerful telescopes both on the ground and in space. Now, to do this, we’ve set up a similar collaboration between the ESOcast, the Hubblecast, the Spitzer Space Telescope’s “Hidden Universe” and the Chandra X-Ray Observatory’s “Beautiful Universe”. I’m Megan Watzke for the Beautiful Universe from the Chandra X-ray Center. I’m Megan Watzke for the Beautiful Universe from the Chandra X-ray Center. It’s the combination of deep observations from many different telescopes that makes this project so important. The longer a telescope spends looking at a target, the more sensitive the observations become, and the deeper we can look into space. But to get the full picture of what’s happening in the Universe, astronomers also need observations at a range of different wavelengths, requiring different telescopes. These are the key ideas behind the Great Observatories Origins Deep Survey, or GOODS for short. The GOODS project unites the world’s most advanced observatories, these include ESO’s Very Large Telescope, the NASA/ESA Hubble Space Telescope, the Spitzer Space Telescope, the Chandra X-ray Observatory and many more, each making extremely deep observations of the distant Universe, across the electromagnetic spectrum. By combining their powers and observing the same piece of the sky, the GOODS observatories are giving us a unique view of the formation and evolution of galaxies across cosmic time, and mapping the history of the expansion of the Universe. Now, this is not the first time that telescopes have been used to give us extremely deep views of the cosmos. For example, the Hubble Deep Field is a very deep image of a small piece of sky in the northern constellation of Ursa Major. This revealed thousands of distant galaxies despite the fact that the whole field is actually only a tiny speck of the sky, about the size of a grain of sand held at arm’s length. Now, with GOODS, many different observatories have brought their powers to bear on two larger targets, one centred on the original Hubble Deep Field in the northern sky, and one centred on a different deep target, the Chandra Deep Field South, in the southern sky. The main GOODS fields are each 30 times larger than the Hubble Deep Field, and additional observations cover an area the size of the full Moon. These areas of the sky were already some of the most extensively explored, and so the combination of existing archival data and many new, dedicated observations gives us an unprecedented view of of the history of galaxies. These areas of the sky were already some of the most extensively explored, and so the combination of existing archival data and many new, dedicated observations gives us an unprecedented view of of the history of galaxies. The NASA/ESA Hubble Space Telescope observed the GOODS regions at optical and nearinfrared wavelengths, to detect distant starforming galaxies among other things. Now, Hubble spent a total of 5 days observing the fields, spread over five repeat visits. Each of these was separated from the previous one by about 45 days. Now, by spreading out the observations like this, Hubble was able to watch for new supernovae appearing over the months, providing key information for studying the expansion and acceleration of the Universe due to the mysterious dark energy. But it wasn’t just Hubble making space-based observations for GOODS ... NASA’s Spitzer Space Telescope imaged the GOODS regions in near- and mid-infrared light for 5 days, at wavelengths up to 30 times longer than the Hubble observations. These longer wavelengths are important for revealing distant galaxies whose light may be obscured by cosmic dust, or stretched by the expansion of the Universe, making them invisible to Hubble. For these distant galaxies, the Spitzer images also tell astronomers about their age and their total mass of stars — complementary information to the data from Hubble. Now, let’s move from the infrared to much shorter wavelengths ... Also in orbit, the Chandra X-Ray Observatory had already observed the GOODS field in many long observations taken over the course of a year. The Chandra images are the deepest X-ray images ever taken, and detected more than 200 hundred X-ray sources believed to be supermassive black holes in the centres of young galaxies. The X-rays are produced by extremely hot interstellar gases falling into the black holes. These multiwavelength observations identified tens of thousands of galaxies. To get a full understanding of the history and development of galaxies over the vast stretch of the Universe’s history, we need to be able to pin down their distances more precisely, to fix them in cosmic time. As these galaxies are so far away, the light waves we see from them started their journey up to about 13 billion years ago, and because the Universe has been expanding since the Big Bang, back then the Universe was less than one seventh of its current size. During the billions of years of the light’s journey, its wavelength has been stretched as the fabric of space has expanded. This effect is known as “redshift” because, for example, light that was originally blue or ultraviolet in colour is shifted to longer, redder wavelengths. Back on the ground, astronomers used spectrographs on ESO’s Very Large Telescope to capture the spectra of galaxies, spreading out their light like the colours of a rainbow. Now, the spectra allow astronomers to measure the redshifts of the galaxies, and hence, their distances. An extensive campaign produced redshifts for almost 3000 galaxies in the GOODS fields. Now, with this knowledge, we can place the galaxies at distances along a vast cone of space, stretching out from our own vantage point like a searchlight beam into the cosmos. We can take an amazing journey through kind of a tunnel towards the edge of the Universe. In some places, the galaxies cluster together, forming structures which are up to tens of millions of light years in scale. Back on the ground, astronomers used spectrographs on ESO’s Very Large Telescope to capture the spectra of galaxies, spreading out their light like the colours of a rainbow. Now, the spectra allow astronomers to measure the redshifts of the galaxies, and hence, their distances. An extensive campaign produced redshifts for almost 3000 galaxies in the GOODS fields. Now, with this knowledge, we can place the galaxies at distances along a vast cone of space, stretching out from our own vantage point like a searchlight beam into the cosmos. We can take an amazing journey through kind of a tunnel towards the edge of the Universe. In some places, the galaxies cluster together, forming structures which are up to tens of millions of light years in scale. Observations at these wavelengths are ideal for finding the redshifted light of distant dusty galaxies in the very early Universe. Because of the longer wavelength of its submillimetre light, the APEX image is not as sharp as the visible light and infrared images. However, thanks to the deep Spitzer images, as well as images made at radio wavelengths, we can match up and identify the objects found by APEX with galaxies seen at other wavelengths. The submillimetre light glow reveals that hundreds of stars are being formed per year in these galaxies. In the next couple of years, ALMA, the Atacama Large Millimeter/submillimeter Array, currently under construction on the same plateau as APEX, will begin its first science observations. Also observing at submillimetre wavelengths, it will have much greater sensitivity than APEX, and resolution even better than Hubble. ALMA will revolutionise our understanding of the early Universe by revealing many more distant, dustobscured galaxies that cannot be seen at all by visible light and infrared telescopes. These projects are an excellent example of how great observatories are joining together, across the electromagnetic spectrum, to give us a more complete view of galaxies over the history of the Universe. Already, astronomers have written over 400 papers based on these data, with even more in the pipeline! And on top of that, the observations of the GOODS fields will continue in the future. These patches of the sky will be prime targets for the next generation of telescopes both on the ground and in space, and astronomers around the world use these data to learn new things about the Universe from them for many years to come. Saying goodbye to our friends at the other observatories, this is Dr J signing off for the ESOcast and the Hubblecast ... This is DrRobert Hurt signing off for the Hidden Universe and the Spitzer Science Center, reminding you there’s a hidden Universe just waiting to be discovered. And this is Megan Watzke signing off for the Chandra X-ray Observatory and the Beautiful Universe. Join me again next time for another cosmic adventure, which I’m sure will surprise us beyond our wildest imagination.

Location

According to the CARMA observatory catalog, the median height of all telescope pads was at an elevation of 2,196.223 meters (7,205.456 ft). The observatory was located in the Inyo Mountains to the east of the Owens Valley Radio Observatory, at a site called Cedar Flat (after relocating the Cedar Flat Group Camps to the west of Hwy-168), accessed through Westgard Pass. The high elevation site was chosen to minimize millimeter wave absorption and phase decoherence by atmospheric water vapor.

Features

This array was unique for being a heterogeneous collection of radio telescopes of varying sizes and design. There were three types of telescopes, all Cassegrain reflector antennas with parabolic primary mirrors and hyperbolic secondary mirrors:

Six telescopes each 10.4 meters (34 ft) in diameter. These were part of the Millimeter Array at the OVRO site operated by Caltech. They were moved to Cedar Flat in the Spring of 2005.
Nine telescopes each 6.1 m (20 ft) in diameter. These were formerly located at the Hat Creek Radio Observatory and operated by the Berkeley-Illinois-Maryland-Association (BIMA) consortium. These were moved from HCRO in the spring of 2005 to Cedar Flat.
Eight telescopes each 3.5 m (11 ft) in diameter. These were built as an instrument for cosmology and are also known as the Sunyaev-Zel'dovich Array (SZA), a project led by John Carlstrom at the University of Chicago. The SZA spent three years on the valley floor at the Owens Valley Radio Observatory observing the cosmic microwave background (CMB) and galaxy clusters. In the summer of 2008 it was moved up to Cedar Flat.

Deployment

As of November 2006^[update], the six telescopes from the OVRO array and the nine telescopes from the BIMA array were working together to gather scientific data. Pioneering work on compensating for the image distortion resulting from turbulent water vapor distributions in the troposphere started in the fall of 2008.

The most extended configurations of the array, up to 2 kilometers (1.2 mi), were required for viewing the finest details in astronomical images.^{[citation needed]} Over these distances the variation in the time of arrival of signals at the different telescopes as they pass through different amounts of water vapor severely limits the quality of images.^[3]

By siting an SZA antenna near each of the CARMA antennas and observing a compact astronomical radio source near the source under study, the properties of the atmosphere could be measured on time scales as short as a couple of seconds. This information could be used in the data reduction process to remove a significant fraction of the degradation caused by the atmospheric scintillation.^[4]

Observations using the SZA (operating at 30 GHz) to make the atmospheric measurements started in November 2008. The SZA has also participated directly in the science operations of CARMA during experiments where all three types of telescopes were attached to the same correlator.

Observations were primarily in the 3 mm range (80–115 GHz) and the 1 mm range (210–270 GHz). These frequencies are useful for detecting many molecular gases, including the second most abundant molecule in the universe, carbon monoxide (CO).

Observing CO is an indirect indicator of the presence of molecular hydrogen gas (the most abundant molecule in the universe) which is difficult to detect directly. Cold dust is also detectable in this wavelength range and can be used to study planet-forming disks around stars, for example. In 2009, the OVRO 10.4 m antennas were instrumented with 27–35 GHz receivers and made observations in the centimeter band in concert with the SZA antennas.^{[citation needed]}

VLBI

CARMA was an array element in the early proof-of-concept observations by the Event Horizon Telescope project, and in 2007 participated in observations which showed that event-horizon-scale structures could be seen in the Milky Way's supermassive black hole, Sgr A*.^[5]

Universities involved

CARMA was a consortium composed of three primary groups.

California Institute of Technology, Berkeley-Illinois-Maryland Association (BIMA), University of Chicago

California Institute of Technology
University of California, Berkeley, Radio Astronomy Laboratory
University of Chicago
University of Illinois at Urbana-Champaign, Laboratory for Astronomical Imaging^[6]
University of Maryland, College Park, Laboratory for Millimeter-wave Astronomy^[7]

References

^ "CARMA Radio Telescope Array in the Inyo Mountains Dedicated May 5". California Institute of Technology. 2006-05-04. Retrieved 2021-12-01.
^ Douglas Bock and the CARMA Team, Combined Array for Research in Millimeter-wave Astronomy, From Planets to Dark Energy: the Modern Radio Universe, October 1-5 2007, The University of Manchester, UK
^ The temporal power spectrum of atmospheric fluctuations due to water vapor (aanda.org)
^ "Beating atmospheric scintillation at millimeter and submillimeter wavelengths". spie.org. Retrieved 2021-12-01.
^ Doeleman, Shepard S.; Weintroub, Jonathan; Rogers, Alan E.E.; Plambeck, Richard; Tilanus, Remo P.J.; Friberg, Per; Ziurys, Lucy M.; Moran, James M.; Corey, Brian; Young, Ken H.; Smythe, Daniel L.; Titus, Michael; Marrone, Daniel P.; Cappallo, Roger J.; Bock, Douglas C.J.; Bower, Geoffrey C.; Chamberlin, Richard; Davis, Gary R.; Krichbaum, Thomas P.; Lamb, James; Maness, Holly; Niell, Authur E.; Roy, Alan; Strittmatter, Peter; Werthimer, Daniel; Whitney, Alan R.; Woody, David (4 September 2008). "Event-horizon-scale structure in the supermassive black hole candidate at the Galactic Centre". Nature. 455 (7209): 78–80. arXiv:0809.2442. doi:10.1038/nature07245. PMID 18769434. S2CID 4424735. Retrieved 21 November 2020.
^ https://web.archive.org/web/20050412085632/http://www.astro.uiuc.edu/projects/lai/
^ http://www.astro.umd.edu/rareas/lma/

External links

Wikimedia Commons has media related to Combined Array for Research in Millimeter-wave Astronomy.

Radio astronomy

Concepts

Units (watt and jansky)
Radio telescope (Radio window)
Astronomical interferometer (History)
Very Long Baseline Interferometry (VLBI)
Astronomical radio source

Radio telescopes
(List)

Individual telescopes	500 meter Aperture Spherical Telescope (FAST, China) Arecibo Telescope (Puerto Rico, US) Caltech Submillimeter Observatory (CSO, US) Effelsberg Telescope (Germany) Galenki RT-70 (Russia) Green Bank Telescope (West Virginia, US) Large Millimeter Telescope (Mexico) Lovell Telescope (UK) Ooty Telescope (India) Qitai Radio Telescope (China) RATAN-600 Radio Telescope (Russia) Sardinia Radio Telescope (Italy) Suffa RT-70 (Uzbekistan) Usuda Telescope (Japan) UTR-2 decameter radio telescope (Ukraine) Yevpatoria RT-70 (Ukraine) Southern Hemisphere HartRAO (South Africa) Parkes Observatory (Australia) Warkworth Radio Astronomical Observatory (NZ)
Interferometers	Allen Telescope Array (ATA, California, US) Atacama Large Millimeter Array (ALMA, Chile) Australia Telescope Compact Array (ATCA, Australia) Australian Square Kilometre Array Pathfinder (ASKAP, Australia) Canadian Hydrogen Intensity Mapping Experiment (CHIME, Canada) Combined Array for Research in Millimeter-wave Astronomy (CARMA, California, US) European VLBI Network (Europe) Event Horizon Telescope (EHT) Giant Metrewave Radio Telescope (GMRT, India) Green Bank Interferometer (GBI, West Virginia, US) Korean VLBI Network (KVN, South Korea) Large Latin American Millimeter Array (LLAMA, Argentina/Brazil) Long Wavelength Array (LWA, New Mexico, US) Low-Frequency Array (LOFAR, Netherlands) MeerKAT (South Africa) Molonglo Observatory Synthesis Telescope (MOST, Australia) Multi-Element Radio Linked Interferometer Network (MERLIN, UK) Murchison Widefield Array (MWA, Australia) Northern Cross Radio Telescope (Italy) Northern Extended Millimeter Array (France) One-Mile Telescope (UK) Primeval Structure Telescope (PaST, China) Square Kilometre Array (SKA, Australia, South Africa) Submillimeter Array (SMA, US) Very Large Array (VLA, New Mexico, US) Very Long Baseline Array (VLBA, US) Westerbork Synthesis Radio Telescope (WSRT, Netherlands)
Space-based	HALCA (Japan) Spektr-R (Russia)