Template:Short description {{#invoke:Infobox|infobox}}Template:Template other{{#invoke:Check for unknown parameters|check|unknown=Template:Main other|preview=Page using Template:Infobox telescope with unknown parameter "_VALUE_"|ignoreblank=y| alt | altitude | angular_resolution | area | built | caption | child | code | commons | coordinates | coords | decommissioned | diameter | diameter2 | diameter3 | discovered | dome | embedded | first_light | focal_length | illuminatedarea | illuminateddiameter | image | image_scale | length | location | locmapin | logo | map_caption | module | mounting | name | nomap | nrhp | namedafter | onlysourced | observatory | organisation | organization | qid | refs | style | suppressfields | wavelength | website | width}}Template:Main other
The Robert C. Byrd Green Bank Telescope (GBT) in Green Bank, West Virginia, US is the world's largest fully steerable radio telescope,<ref>Template:Cite magazine</ref> surpassing the Effelsberg 100-m Radio Telescope in Germany.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> The Green Bank site was part of the National Radio Astronomy Observatory (NRAO) until September 30, 2016. Since October 1, 2016, the telescope has been operated by the independent Green Bank Observatory.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> The telescope's name honors the late Senator Robert C. Byrd who represented West Virginia and who pushed the funding of the telescope through Congress.
The Green Bank Telescope operates at meter to millimeter wavelengths. Its 100-meter diameter collecting area, unblocked aperture, and good surface accuracy provide superb sensitivity across the telescope's full 0.1–116 GHz operating range. The GBT is fully steerable, and 85 percent of the local celestial hemisphere is accessible. It is used for astronomy about 6500 hours every year, with 2000–3000 hours per year going to high-frequency science. Part of the scientific strength of the GBT is its flexibility and ease of use, allowing for rapid response to new scientific ideas. It is scheduled dynamically to match project needs to the available weather. The GBT is also readily reconfigured with new and experimental hardware. The high-sensitivity mapping capability of the GBT makes it a vital complement to the Atacama Large Millimeter Array, the Expanded Very Large Array, the Very Long Baseline Array, and other high-angular resolution interferometers. Facilities of the Green Bank Observatory are also used for other scientific research, for many programs in education and public outreach, and for training students and teachers.
The telescope began regular science operations in 2001, making it one of the newest astronomical facilities of the US National Science Foundation (NSF). It was constructed following the collapse of a previous telescope at Green Bank, the 300 Foot Radio Telescope, a 90.44 m paraboloid that began observations in October 1961.<ref>Template:Cite encyclopedia</ref> This previous telescope collapsed on 15 November 1988 due to the failure of a gusset plate in the box girder assembly, which was a key component for the structural integrity of the telescope.<ref>NRAO 300 foot Telescope Collapse</ref><ref name="constructionPeriod">Template:Cite press release</ref>
LocationEdit
The telescope sits near the heart of the United States National Radio Quiet Zone, a unique area located in the town of Green Bank, West Virginia, where authorities limit all radio transmissions to avoid emissions toward the GBT and the Sugar Grove Station. The location of the telescope within the Radio Quiet Zone allows for the detection of faint radio-frequency signals which human-made signals might otherwise mask. The observatory borders National Forest land, and the Allegheny Mountains shield it from some radio interference.
The telescope's location has been the site of important radio astronomy telescopes since 1957.<ref name="NRAO2007">Template:Cite book</ref> It currently houses seven additional telescopes, and in spite of its somewhat remote location, receives about 40,000 visitors each year.<ref name="Website">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>
DescriptionEdit
The structure weighs Template:Convert and is Template:Convert tall. The surface area of the GBT is a 100 by 110 meter active surface with 2,209 actuators (small motors used to adjust the position) for the 2,004 surface panels, making the total collecting area of Template:Convert.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref><ref name=Frayer>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> The panels are made from aluminum manufactured to a surface accuracy of better than Template:Convert RMS.<ref>Template:Cite journal</ref> The actuators adjust the panel positions to compensate for sagging, or bending under its own weight, which changes as the telescope moves. Without this so-called "active surface" adjustment, observations at frequencies above 4 GHz would not be as efficient.<ref name=gbtpg>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>
Unusual for a radio telescope, the primary reflector is an off-axis segment of a paraboloid. This is the same design used in smaller (eg., 45-100cm) home satellite television dishes. The asymmetric reflector allows the telescope's focal point and feed horn to be located at the side of the dish, so that it and its retractable support boom do not obstruct the incoming radio waves, as occurs in conventional radio telescope designs with the feed located on the telescope's beam axis.
The Template:Convert offset support arm houses a prime focus receiver on a retractable boom in front of a subreflector, and a receiver room.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref><ref name=GBTDesign>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> For prime focus operation, the boom is extended to position the feed horn in front of the 8 m subreflector. For Gregorian focus operation, the prime focus boom is retracted. The subreflector, positioned by a Stewart platform with 6 degrees of freedom, reflects incoming radio waves toward eight higher-frequency feeds on a rotating turret located on top of the receiver room. The computerized controlled turret can rotate a particular receiver into the position within a few minutes.<ref>Template:Cite journal</ref> Operational frequencies range from 290 MHz to 115 GHz.<ref name=gbtpg />
As an azimuth-elevation mounting telescope, the azimuth adjustments are driven by four trucks with four wheels each on a Template:Convert diameter rail. The 16 thirty-horsepower motors can change azimuth at the rate of up to 40 degrees per minute.<ref name=Lockman>Template:Cite tech report</ref> Azimuth axis is also supported by a pintle bearing at the center point of the azimuth track.<ref name=GBTDesign/>
The elevation wheel structure provides tilting capability to adjust elevations between 5 and 95 degrees. The Template:Convert radius bull gear on the elevation wheel is driven by eight 40 horsepower motors with a capability of changing the elevations up to 20 degrees per minute. The Template:Convert long and Template:Convert diameter elevation shaft provides primary support of the wheel structure. The elevation wheel also contains concrete-filled counterweight to balance with the surface and the feed arm structure.<ref name=Lockman/><ref name=Reid>Template:Cite magazine</ref>
- Green Bank Telescope components
- Green Bank Telescope - surface panel actuators.jpg
CitationClass=web }}</ref>
- GBT Secondary.png
CitationClass=web }}</ref>
- Green Bank Telescope - Gregorian focus operation.jpg
Gregorian focus operation: subreflector (top), rectracted boom (middle), and receiver turret (bottom)<ref name=Armentrout>Template:Cite document</ref>
- GBT Receiver.png
Underside of the turret inside the receiver room<ref name=Armentrout/>
- GBT Elevator.png
Access way to focal point<ref name=GBTDesign/>
- Green Bank Telescope - elevation wheel.jpg
Elevation wheel with counterweight and bull gear (bottom), and elevation shaft (across from left to right)<ref name=Reid/>
- GBT Altitude.png
Elevation drive<ref name=GBTDesign/>
- Green Bank Telescope - elevation bearing.jpg
Elevation bearing (center)<ref name=GBTDesign/>
- Green Bank Telescope - azimuth track and pintle bearing.jpg
Four azimuth trucks (on the circular track) and pintle bearing (bottom center)<ref name=GBTDesign/>
- GBT Azimuth.png
CitationClass=web }}</ref>
Because of its height (at 148 meters or 485 feet tall, it is 60% taller than the Statue of Liberty) and bulk (16 million pounds), locals sometimes refer to the GBT as the “Great Big Thing”.<ref>Jim Merithew, “Silence! The Last of the Giant Radio Telescopes Is Listening to the Universe”, Wired (October 2009)</ref><ref>John M Thompson, “W.Va. Observatory Scans the Universe for Radio Signals”, The Washington Post (19 November 2008)</ref>
The telescope's capabilities include the ngRADAR system which use the dish as a radar transmitting antenna to observe solar system objects such as asteroids.<ref>Lewis, Briley, "New Space Radar Will Hunt Planet-Threatening Asteroids" Scientific American, (21 February 2023).</ref> Its low power prototype (700 watts at Ku band), with reception at the Very Long Baseline Array, has already imaged the moon and asteroid (231937) 2001 FO32. <ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>
DiscoveriesEdit
In 2002, astronomers detected three new millisecond pulsars in the globular cluster Messier 62.<ref>Template:Cite press release</ref>
In 2006, several discoveries were announced, including a large coil-shaped magnetic field in the Orion molecular cloud,<ref>Green Bank Telescope scores big finds in space: Fastest pulsar Slinky magnetics superbubble of hydrogen ID, The Charleston Gazette, 2006-01-17</ref> and a large hydrogen gas superbubble 23,000 light years away, named the Ophiuchus Superbubble.<ref>Template:Cite journal</ref><ref name='huge superbubble'>Template:Cite news</ref>
In 2019, the most massive neutron star PSR J0740+6620 to date was detected.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> Since 2004, 28 new complex molecules have been discovered in the interstellar medium with the Green Bank Telescope.<ref>Template:Cite journal</ref>
Funding threatenedEdit
In response to limited budgetary issues, the Division of Astronomical Sciences (AST) of the National Science Foundation (NSF) commissioned a portfolio review committee, which conducted its work between September 2011 and August 2012.<ref name=astReview>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref><ref name=astWebinar>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref><ref name="scienceOnline2012-08-17">Template:Cite journal</ref> The committee, which reviewed all AST-supported facilities and activities, was composed of 17 external scientists and chaired by Daniel Eisenstein of Harvard University.<ref name=astReview /><ref name=astWebinar /><ref name="scienceOnline2012-08-17" /><ref name="physicsWorld2012-08-22">Template:Cite magazine</ref> As part of the committee's August 2012 recommendation for the closure of six facilities, was that the Robert C. Byrd Green Bank Telescope (GBT) should be defunded over a five-year period.<ref name="scienceOnline2012-08-17" /><ref name="physicsWorld2012-08-22" /><ref>Template:Cite journal</ref>
In July 2014, the United States Senate Committee on Appropriations approved the NSF's fiscal year 2014 budget, which did not call for divestment of the GBT in that fiscal year. The facility then began looking for partners to help fund its $10 million annual operating costs.<ref>Template:Cite magazine</ref>
On October 1, 2016, the National Radio Astronomy Observatory at Green Bank separated from the NSF and began accepting funding from private sources to stay operational as an independent institution, the Green Bank Observatory.<ref name="wired_2016-10-07">Template:Cite magazine</ref>
Relation to Breakthrough ListenEdit
The telescope is a key facility of the Breakthrough Listen project,<ref>Template:Cite magazine</ref> in which it is used to scan for radio signals possibly emitted by extraterrestrial technologies. In late 2017, the telescope was used to scan the interstellar object ʻOumuamua for signs of extraterrestrial intelligence as it passed through the Solar System.<ref>Template:Cite news</ref><ref name=Enriquez2018a>Template:Cite journal</ref>