Arecibo Radio Telescope | |
Organization | Cornell University, NSF |
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Location | Arecibo, Puerto Rico |
Wavelength | radio (3 cm–1 m) |
Built | 1963 |
Telescope style | spherical reflector |
Diameter | 305 m (1,001 ft) |
Collecting area | ~73,000 m², ~790,000 ft², ~18 acres |
Focal length | 265.109 m, 869 ft 9.38 in (265.1095 m) |
Mounting | semi-transit telescope: fixed primary with secondary (Gregorian reflector) and a delay-line feed, each of which moves on tracks to point to different parts of the sky. |
Dome | none |
Website | www.naic.edu |
National Astronomy and Ionosphere Center | |
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U.S. National Register of Historic Places | |
U.S. Historic District | |
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Coordinates: | |
Area: | 118 acres |
Architect: | Gordon, William E; Kavanaugh, T.C. |
Governing body: | Federal |
Added to NRHP: | September 23, 2008[1] |
NRHP Reference#: | 07000525 |
The Arecibo Observatory is a radio telescope located close to the city of Arecibo in Puerto Rico. It is operated by Cornell University under cooperative agreement with the National Science Foundation. The observatory works as the National Astronomy and Ionosphere Center (NAIC) although both names are officially used to refer to it. NAIC more properly refers to the organization that runs both the observatory and associated offices at Cornell University.
The observatory's 305 m (1,001 ft) radio telescope is the largest single-aperture telescope (cf. multiple aperture telescope) ever constructed. It carries out three major areas of research: radio astronomy, aeronomy (using both the 305 m telescope and the observatory's lidar facility), and radar astronomy observations of solar system objects. Usage of the telescope is gained by submitting proposals to the observatory, which are evaluated by an independent board of referees.
The telescope is visually distinctive and has been used in the filming of notable motion picture and television productions. The telescope received additional international recognition in 1999 when it began to collect data for the SETI@home project.
The center was listed on the U.S. National Register of Historic Places in 2008.[1][2] The listing was announced as the featured listing in the National Park Service's weekly list of October 16, 2009.[3]
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Opened in 1997, the Angel Ramos Foundation Visitor Center features interactive exhibits and displays about the operations of the radio telescope, astronomy, and atmospheric science. The center is named after the foundation created by Ángel Ramos, the founder of Telemundo, which provided one half of the construction costs for building the center.
The Arecibo telescope is distinguished by its enormous size: the main collecting dish is 305 m (1,001 ft) in diameter, constructed inside the depression left by a karst sinkhole.[4] According to the blueprint published in the observatory's guidebook, the dish is actually 848.7 feet across, therefore, the oft-published 1,000-foot dimension is apparently along the spherical curve of the dish. The dish is the largest curved focusing dish on Earth, giving Arecibo the largest electromagnetic-wave-gathering capacity.[5] The Arecibo telescope's dish surface is made of 38,778 perforated aluminum panels, each measuring about 1 m by 2 m (3 ft by 6 ft, 1 yd by 2 yd), supported by a mesh of steel cables.
The telescope has three radar transmitters, with effective isotropic radiated powers of 20TW at 2380 MHz, 2.5TW (pulse peak) at 430 MHz, and 300MW at 47 MHz.
The telescope is a spherical reflector (as opposed to a parabolic reflector). This form is due to the method used to aim the telescope: the telescope's dish is fixed in place, and the receiver is repositioned to intercept signals reflected from different directions by the spherical dish surface. A parabolic mirror would induce a varying astigmatism when the receiver is in different positions off the focal point, but the error of a spherical mirror is the same in every direction. The receiver is located on a 900-ton platform which is suspended 150 m (500 ft) in the air above the dish by 18 cables running from three reinforced concrete towers, one of which is 110 m (365 ft) high and the other two of which are 80 m (265 ft) high (the tops of the three towers are at the same elevation). The platform has a 93-meter-long rotating bow-shaped track called the azimuth arm on which receiving antennas, secondary and tertiary reflectors are mounted. This allows the telescope to observe any region of the sky within a forty-degree cone of visibility about the local zenith (between -1 and 38 degrees of declination). Puerto Rico's location near the equator allows Arecibo to view all of the planets in the solar system, though the round trip light time to objects beyond Saturn is longer than the time the telescope can track it, preventing radar observations of more distant objects.
The construction of the Arecibo telescope was initiated in the summer of 1960 and completed in November, 1963, by Professor William E. Gordon and Zachary Sears of Cornell University, who originally intended to use it for the study of Earth's ionosphere.[6][7][8] Originally, a fixed parabolic reflector was envisioned, pointing in a fixed direction with a 150 m (500 ft) tower to hold equipment at the focus. This design would have had a very limited use for other potential areas of research, such as planetary science and radio astronomy, which require the ability to point at different positions in the sky and to track those positions for an extended period as Earth rotates. Ward Low of the Advanced Research Projects Agency (ARPA) pointed out this flaw, and put Gordon in touch with the Air Force Cambridge Research Laboratory (AFCRL) in Boston, Massachusetts where a group headed by Phil Blacksmith was working on spherical reflectors and another group was studying the propagation of radio waves in and through the upper atmosphere. Cornell University proposed the project to ARPA in the summer of 1958 and a contract was signed between the AFCRL and the University in November 1959. Cornell University, and Zachary Sears published a request for proposals (RFP) asking for a design to support a feed moving along a spherical surface 435 feet (133 m) above the stationary reflector. The RFP suggested a tripod or a tower in the center to support the feed. At Cornell University, the day the project for the design and construction of the antenna was announced, William Gordon had also envisioned a 435 ft. tower located in the center of the 1,000 ft. reflector for the feed's support.
George Doundoulakis, Director of Research at General Bronze Corporation in Garden City, New York, along with Zachary Sears, the Director of Internal Design at Digital B & E Corporation, New York, received the request for proposal (RFP) from Cornell University for the antenna design, and studied the idea of suspending the feed with his brother, Helias Doundoulakis, a civil engineer. George Doundoulakis identified the problem that a tower or tripod would have presented around the center, the most important area of the reflector, and devised a more efficient, cost-effective approach by suspending the feed. He presented his proposal to Cornell, by utilizing a doughnut truss suspended by four cables from four towers above the reflector, and providing along its edge a rail track for the azimuthal positioning of the feed. A second truss, in the form of an arc, or arch, was to be suspended below, which would rotate on the rails through 360 degrees. The arc also provided rails onto which the unit supporting the feed would move to provide for the elevational positioning of the feed. A counter-weight would move symmetrically opposite to the feed for stabilitiy, and the entire feed could be lowered and raised if a hurricane were present. Helias Doundulakis ultimately designed the cable suspension system which was adopted in the final construction. Although the present configuration is substantially the same as the original drawings by George and Helias Doundoulakis (with the exception of the suspension of the feed positioning assembly by three towers rather than four in the original proposal), the U.S. Patent office granted Helias Doundoulakis a patent[9] for he and his brother's innovative idea, with William J. Casey, ex-Director of the CIA under President Ronald Reagan, also an assignee on the patent.
Construction began in the summer of 1960, with the official opening on November 1, 1963.[10] As the primary dish is spherical, its focus is along a line rather than at a single point (as would be the case for a parabolic reflector), thus complicated 'line feeds' had to be used to carry out observations. Each line feed covered a narrow frequency band (2-5% of the center frequency of the band) and a limited number of line feeds could be used at any one time, limiting the flexibility of the telescope.
The telescope has undergone significant upgrades. Initially, when the maximum expected operating frequency was about 500 MHz, the surface consisted of half-inch galvanized wire mesh laid directly on the support cables. In 1974, a high precision surface consisting of thousands of individually adjustable aluminum panels replaced the old wire mesh, and the highest usable frequency was raised to about 5000 MHz. A Gregorian reflector system was installed in 1997, incorporating secondary and tertiary reflectors to focus radio waves at a single point. This allowed the installation of a suite of receivers, covering the whole 1–10 GHz range, that could be easily moved onto the focal point, giving Arecibo a new flexibility. At the same time, a ground screen was installed around the perimeter to block the ground's thermal radiation from reaching the feed antennas, and a more powerful 2400 MHz transmitter was installed.
Many significant scientific discoveries have been made using the Arecibo telescope. On 7 April 1964, shortly after its inauguration, Gordon Pettengill's team used it to determine that the rotation rate of Mercury was not 88 days, as previously thought, but only 59 days.[11] In 1968, the discovery of the periodicity of the Crab Pulsar (33 milliseconds) by Lovelace and others provided the first solid evidence that neutron stars exist in the Universe.[12] In 1974 Hulse and Taylor discovered the first binary pulsar PSR B1913+16,[13] for which they were later awarded the Nobel Prize in Physics. In 1982, the first millisecond pulsar, PSR B1937+21, was discovered by Donald C. Backer, Shrinivas Kulkarni, Carl Heiles, Michael Davis, and Miller Goss.[14] This object spins 642 times per second, and until the discovery of PSR J1748-2446ad in 2005, it was the fastest-spinning pulsar known.
In August 1989, the observatory directly imaged an asteroid for the first time in history: 4769 Castalia.[15] The following year, Polish astronomer Aleksander Wolszczan made the discovery of pulsar PSR B1257+12, which later led him to discover its three orbiting planets and a possible comet.[16][17] These were the first extra-solar planets ever discovered. In 1994, John Harmon used the Arecibo radio telescope to map the distribution of ice in the poles of Mercury.[18]
In January 2008, detection of prebiotic molecules methanimine and hydrogen cyanide were reported from Arecibo Observatory radio spectroscopy measurements of the distant starburst galaxy Arp 220.[19]
The telescope also had military intelligence uses, for example in locating Soviet radar installations by detecting their signals bouncing back off the Moon. Arecibo is also the source of data for the SETI@home and Astropulse distributed computing projects put forward by the Space Sciences Laboratory at the University of California, Berkeley and was used for the SETI Institute's Project Phoenix observations.[20]
In 1974, the Arecibo message, an attempt to communicate with potential extraterrestrial life, was transmitted from the radio telescope toward the globular cluster M13, about 25,000 light-years away.[21] The 1,679 bit pattern of 1s and 0s defined a 23 by 73 pixel bitmap image that included numbers, stick figures, chemical formulas, and a crude image of the telescope itself.[22] Terrestrial aeronomy experiments include the Coqui 2 experiment.
A report by the division of Astronomical Sciences of the National Science Foundation, made public on 2006-11-03, recommended substantially decreased astronomy funding for Arecibo Observatory, ramping down from US$10.5M in 2007 to US$4M in 2011.[23][24] If other sources of funding cannot be obtained, this would mean the closure of the observatory. The report also advised that 80% of the observation time be allocated to the surveys already in progress, reducing the time available for other scientific work. NASA gradually eliminated its share of the planetary radar funding at Arecibo from 2001–2006.[25]
In response to these threats, academics and researchers have organized themselves with the purpose of protecting and advocating for the future of Arecibo Observatory. They have established the Arecibo Science Advocacy Partnership (ASAP), whose mission statement is to advance the scientific excellence of Arecibo Observatory research and to publicize its accomplishments in astronomy, aeronomy and planetary radar.[26] Among several goals of ASAP are to: mobilize the existing broad base of support for Arecibo science within the fields it serves directly, the broad scientific community, and the general public; provide a forum for the Arecibo research community and enhance communication within it; promote the potential of Arecibo for groundbreaking science, and suggest the paths that will maximize it into the foreseeable future; showcase the broad impact and far-reaching implications of the science currently carried out with this unique instrument.[26]
Contributions by the government of Puerto Rico may be one way to help fill the funding gap, but are controversial and uncertain. At town hall meetings about the potential closure, Puerto Rico Senate President Kenneth McClintock announced an initial local appropriation of $3 million during fiscal year 2008 to fund a major maintenance project to restore the three pillars from which the antenna platform is suspended to their original condition, pending inclusion in the next bond issue.[27] The bond authorization, with the $3 million appropriation, was approved by the Senate of Puerto Rico on November 14, 2007, the first day of a special session called by Aníbal Acevedo Vilá.[28] The Puerto Rico House of Representatives repeated this action on June 30, 2008. The Governor signed the measure into law in August 2008.[29] These funds are expected to be made available beginning in the second half of 2009.
José Serrano, a member of the U.S. House of Representatives Appropriations Committee, asked the National Science Foundation to keep Arecibo in operation in a letter released on September 19, 2007.[30] Language similar to that in the September 19 letter was included in the FY'08 omnibus spending bill. In October 2007, Puerto Rico's Resident Commissioner (now governor), Luis Fortuño, along with Dana Rohrabacher, filed legislation to assure the continued operation of the facility.[31] A similar bill was filed in the United States Senate in April, 2008 by the junior Senator from New York, Hillary Clinton.[32]
As the Arecibo facility is owned by the United States, and administered as a national facility by the NAIC, direct donations by private or corporate donors cannot be made. However, as a non-profit, non-government institution, Cornell University will accept contributions on behalf of Arecibo Observatory.[33] It has been suggested by at least one member of the NAIC staff that Google purchase advertising space on the dish as one means of securing additional non-government funds.[34]
In September 2007, in an open letter to researchers, the NSF clarified the status of the budget issue for NAIC, stating that the present plan, if implemented, may hit the targeted budgetary revision.[35] No mention of private funding was made. However, it need be noted that the NSF is undertaking studies to mothball, or deconstruct the facility and return it to its natural setting in the event that the budget target is not achieved. In November 2007, The Planetary Society urged Congress to prevent the Arecibo Observatory from closing due to insufficient funds,[36] since the radar contributes heavily[37] to the accuracy of asteroid impact prediction, and they believe continued operation will reduce the cost of mitigation (that is, deflection of NEA on collision to Earth), should that be necessary.
In July 2008, the British newspaper The Daily Telegraph reported that the funding crisis, due to federal budget cuts, was still very much alive.[38] The SETI@home program is using the telescope as a primary source for the research. The program is urging people to send a letter to their political representatives, in support of full federal funding of the observatory.[39]
NAIC is expected to receive US$3.1 million from the American Recovery and Reinvestment Act of 2009 (ARRA, a.k.a. the stimulus package). This would be an in increase of around 30% over the FY2009 budget. However, the FY2010 funding request by NSF was cut by US$1.2 million (-12.5% over the non-ARRA supported FY2009 budget) in light of their continued plans to reduce funding.[40] The 2011 NSF budget request is reduced by a further US$1.6 million, -15% with respect to 2010, with a further US$1 million reduction projected by FY2014.[41] In addition, "NSF will decertify NAIC as a Federally Funded Research and Development Center (FFRDC) upon award of the next cooperative agreement for its management and operation."[41]
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