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Palomar Observatory

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Palomar Observatory
Palomar Observatory and Hale Telescope dome
Alternative names675 PA Edit this at Wikidata
OrganizationCalifornia Institute of Technology
Observatory code 675 Edit this on Wikidata
LocationSan Diego County, California
Coordinates33°21′21″N 116°51′50″W / 33.35583°N 116.86389°W / 33.35583; -116.86389
Altitude1,712 meters (5,617 ft)
Established1928
WebsitePalomar at Caltech
Telescopes
Hale Telescope5.1 m reflector
60-inch Telescope1.5 m reflector
Samuel Oschin Telescope1.2 m Schmidt Reflector
unnamed telescope0.6 m reflector
Palomar Observatory is located in the United States
Palomar Observatory
Location of Palomar Observatory
  Related media on Commons

Palomar Observatory is an astronomical observatory located in San Diego County, California, United States, 145 kilometers (90 mi) southeast of Los Angeles, California, in the Palomar Mountain Range. It is owned and operated by the California Institute of Technology (Caltech) located in Pasadena, California. Research time is granted to Caltech and its research partners, which include the Jet Propulsion Laboratory (JPL) and Cornell University.[1]

The observatory operates several telescopes, including the famous 200-inch (5.1 m) Hale Telescope and the 48-inch (1.2 m) Samuel Oschin Telescope. In addition, other instruments and projects have been hosted at the observatory, such as the Palomar Testbed Interferometer and the historic 18-inch (0.46 m) Schmidt telescope, Palomar Observatory's first telescope, dating from 1936.

History

Hale's vision for large telescopes and Palomar Observatory

Astronomer George Ellery Hale, whose vision created the Palomar Observatory, built the world's largest telescope four times. He published an article in the April 1928 issue of Harper's Magazine called "The Possibilities of Large Telescopes". This article contained Hale's vision for building what was to become the 200-inch Palomar reflector; it was an invitation to the American public to learn about how large telescopes could help answer questions relating to the fundamental nature of the universe. Hale hoped that the American people would understand and support his project. In fact, the 200-inch telescope was the most important telescope in the world from 1949 until 1992, when the W. M. Keck Observatory built the Keck I telescope (at approximately 10 meters (390 in)) on Mauna Kea in Hawaii which became the world's largest.

Hale followed this article with a letter to the International Education Board (later absorbed into the General Education Board) of the Rockefeller Foundation dated April 28, 1928, in which he requested funding for this project. In his letter, Hale stated:

"No method of advancing science is so productive as the development of new and more powerful instruments and methods of research. A larger telescope would not only furnish the necessary gain in light space-penetration and photographic resolving power, but permit the application of ideas and devices derived chiefly from the recent fundamental advances in physics and chemistry."

Etymology

The word palomar is a Spanish term dating from the time of Spanish California that means pigeon house (in the same sense as henhouse). The name may be in reference to the large flocks of pigeons that can be seen during the spring and autumn months atop Palomar Mountain, or reminiscent of an old pigeon-raising facility built there by the Spaniards.[citation needed]

The Hale Telescope

The 200-inch telescope is named after astronomer George Hale. It was built by Caltech with a $6 million grant from the Rockefeller Foundation, using a Pyrex blank manufactured by Corning Glass Works. Dr. J.A. Anderson was the initial project manager assigned in the early 1940s.[2] The telescope (the largest in the world at that time) saw first light January 26, 1949 targeting NGC 2261.[3] The American astronomer Edwin Powell Hubble, perhaps the most important observer of the 20th century, was given the honor of being the first astronomer to use the telescope.

Astronomers using the Hale Telescope have discovered distant objects at the edges of the known universe called quasars and have given us the first direct evidence of stars in distant galaxies. They have studied the structure and chemistry of intergalactic clouds, leading to an understanding of the synthesis of elements in the universe, and have discovered thousands of asteroids. A one-tenth-scale engineering model of the telescope at Corning Community College in Corning, New York, home of the Corning Glass Works (now Corning Incorporated) was used to discover at least one minor planet, (34419) Corning.JPL

Architecture and design

Hale Telescope Dome

According to the Observatory's Public Affairs Office, Russell W. Porter was primarily responsible for the Art Deco architecture of the Observatory's buildings, most notably the dome of the 200–inch Hale Telescope. Porter was also responsible for much of the technical design of the Hale Telescope and Schmidt Cameras, producing a series of cross-section engineering drawings that are considered among the finest examples of such work.[citation needed] Porter worked on the designs in collaboration with many engineers and Caltech committee members. The gleaming white building on Palomar Mountain that houses the 200–inch Hale Telescope is considered by many[who?] to be "The Cathedral of Astronomy".[citation needed]

Directors

Palomar Observatory and light pollution

Much of the surrounding region of Southern California has adopted shielded lighting to reduce the light pollution that would potentially affect the observatory.[4]

Telescopes and instruments

Astronomer Jean Mueller posing with the Samuel Oschin Telescope (Schmidt Camera)

Former instruments

  • An 18-inch Schmidt camera became the first operational telescope at the Palomar in 1936. In the 1930s a Caltech astronomer named Fritz Zwicky discovered over 100 supernovae (exploding stars) in other galaxies with this telescope and gathered the first evidence for dark matter. Comet Shoemaker-Levy 9 was discovered with this instrument in 1993. It has since been retired and is on display at their small museum/visitor center.[9]
  • The Palomar Testbed Interferometer was a multi-telescope instrument that permitted astronomers to make very high resolution measurements of the sizes and positions of objects in space. The shapes of some bright stars have been measured with the PTI. It operated from 1995 to 2008.[10]
  • The Palomar Planet Search Telescope (PPST), aka Sleuth, was a 0.1 m (3.9 in) robotic telescope that operated from 2003 until 2008. It was dedicated to the search for planets around other stars using the transit method. It operated in conjunction with telescopes at Lowell Observatory and in the Canary Islands as part of the Trans-atlantic Exoplanet Survey (TrES).[11]

Research

The observatory has completed several astronomical surveys: the first in the 1950s, the second in the 1980s and 1990s, and a third in 2003.

POSS-I

The initial Palomar Observatory Sky Survey (POSS or POSS-I), sponsored by the National Geographic institute, was completed in 1958. The first plates were shot in November 1948 and the last in April 1958. This survey was performed using 14 inch2 (6 degree2) or blue-sensitive (Kodak 103a-O) and red-sensitive (Kodak 103a-E) photographic plates on the 48-inch Samuel Oschin Schmidt reflecting telescope. The survey covered the sky from a declination of +90 degrees (celestial north pole) to -27 degrees and all right ascensions and had a sensitivity to +22 magnitudes (about 1 million times fainter than the limit of human vision). A southern extension extending the sky coverage of the POSS to -33 degrees declination was shot in 1957 - 1958. The final POSS I consisted of 937 plate pairs.

Fritz Zwicky was the first astronomer to observe on Mt. Palomar and was the father of the Sky Survey Technique.[12]

Digitized Sky Survey (DSS) produced images which were based on the photographic data developed in the course of POSS-I.[13]

J.B. Whiteoak, an Australian radio astronomer, used the same instrument to broaden this POSS-I data further. Whiteoaks observations extended south to about -45 degrees declination, using the same field centers as the corresponding northern declination zones. Unlike POSS-I, the Whiteoak extension consisted only of red-sensitive (Kodak 103a-E) photographic plates.

POSS-II

The Second Palomar Observatory Sky Survey (POSS-II) was performed in the 1980s and 1990s that made use of better, faster films and an upgraded telescope. The Oschin Schmidt was given an achromatic corrector and provisions for autoguiding. Images were recorded in three wavelengths: blue (IIIaJ), red (IIIaF) and near infrared (IVN) plates, respectively. Observers on POSS II included C. Brewer, D. Griffiths, W. McKinley, D. Mendenhall, K. Rykoski, J. Phinney and Jean Mueller (who discovered over 100 supernovae by comparing the POSS I and POSS II plates). Mueller also discovered several comets during the course of POSS II and the bright Comet Wilson 1986 was discovered by then graduate student C. Wilson early in the survey.[14]

Until the completion of the Two Micron All Sky Survey (2MASS), POSS-II was the most extensive wide-field sky survey ever. When completed, the Sloan Digital Sky Survey will surpass POSS-I and POSS-II in depth, although the POSS covers almost 2.5 times more area on the sky.

POSS-II also exists in digitized form (i.e., the photographic plates were scanned), both in photographic form as the Digitized Sky Survey (DSS)[15][clarification needed]

QUEST

The multi-year POSS projects were followed by the Palomar Quasar Equatorial Survey Team (QUEST) Variability survey.[16] This survey yielded results that were used by several projects, including the Near-Earth Asteroid Tracking project. Another program that used the QUEST results discovered 90377 Sedna on 14 November 2003, and around 40 Kuiper belt objects. Other programs that share the camera are Shri Kulkarni's search for gamma-ray bursts (this takes advantage of the automated telescope's ability to react as soon as a burst is seen and take a series of snapshots of the fading burst), Richard Ellis' search for supernovae to test whether the universe's expansion is accelerating or not, and S. George Djorgovski's quasar search.

The camera for the Palomar QUEST Survey was a mosaic of 112 Charge-coupled devices (CCDs) covering the whole (4 degree by 4 degree) field of view of the Schmidt telescope, the largest CCD mosaic used in an astronomical camera when built. This instrument was used to produce The Big Picture, the largest astronomical photograph ever produced.[17] The Big Picture is on display at Griffith Observatory.

Current research

Current research programs on the 200-inch Hale Telescope cover the range of the observable universe including studies on near-Earth asteroids, outer solar system planets, Kuiper Belt Objects, star formation, exoplanets,[18] gamma-ray bursts, black holes, quasars and much more.[19]

The 48-inch Samuel Oschin Schmidt Telescope is actively working on a new sky survey, the Palomar Transient Factory (PTF).[20]

The 60-inch telescope is used for a variety of projects including follow-up observations for the Palomar Transient Factory and is a rapid response telescope for gamma-ray bursts.

Clearest images

In September 2007, a team of astronomers from the United States and Britain released some of the clearest pictures ever taken of outer space. The pictures were obtained through the use of a new hybrid "Lucky imaging" and "adaptive optics" system that sharpens pictures taken from the Palomar Observatory. The resolution attained exceeds that of the Hubble Space Telescope by a factor of two.[21]

Visiting

The Palomar Observatory is an active research facility. However, parts of it are open to the public during the day. Visitors can take self-guided tours of the 200-inch telescope daily from 9 a.m. to 3 p.m. The observatory is open 7 days a week, year round, except for December 24 and 25 and during times of inclement weather. Guided tours of the 200-inch Hale Telescope dome and observing area are available Saturdays and Sundays from April through October. Details are available at the Observatory's web site. There is a visitor's center and a gift shop on the grounds. Behind-the-scenes tours for the public are offered through the community support group, Friends of Palomar support group. Periodic tours are also organized by the Reuben H. Fleet Science Center in San Diego.[22] The observatory is located off State Route 76 in northern San Diego County, California, is two hours' drive from downtown San Diego, and three hours' drive from central Los Angeles ( UCLA, LAX airport ).

In the October 11 and 12, 1989, Calvin and Hobbes comic strips, Calvin has a dream where Stupendous Man takes the lens from the Palomar Observatory telescope and uses it to destroy his school.[23]

Canadian band The Rheostatics' 1992 release Whale Music features a track entitled "Palomar." The song depicts a man named Palomar on the top of a mount, cleaning his lenses with saline waters, and assembling his kaleidoscope in his lonely observatory. The song presents a visual characterization of a man on a mountain and his relationship with his best friend, a dog.

In 1994, Palomar is mentioned in the first episode of season 2 of The X-Files, "Little Green Men". Fox Mulder refers to Hale's suggestion that an elf[24] crawled through his window and told him to build the observatory.

The band Wellwater Conspiracy's 1997 debut album, Declaration of Conformity, contains an instrumental track entitled "Palomar Observatory." Wellwater Conspiracy singer/drummer Matt Cameron grew up in San Diego near the observatory.

Selected books

See also

References

  1. ^ Cornell University, Dept. of Astronomy: Palomar Observatory
  2. ^ Super Camera of the Skies." Popular Mechanics, April 1942, p. 52.
  3. ^ "60th Anniversary of Hale Telescope," 365 Days of Astronomy (podcast). January 26, 2009.
  4. ^ International Dark-Sky Association (IDA): "Sky Glow Effect on Existing Large Telescopes", IDA Info #20.
  5. ^ "Caltech Astronomy - The 200-inch Hale Telescope". Caltech Astronomy. Retrieved 2014-12-09.
  6. ^ "Caltech Astronomy - The 60-inch Telescope". Caltech Astronomy. Retrieved 2014-12-09.
  7. ^ "Caltech Astronomy - Samuel Oschin Telescope". Caltech Astronomy. Retrieved 2014-12-09.
  8. ^ "Caltech Astronomy - Discoveries from Palomar Observatory's 48-inch Samuel Oschin Telescope". Caltech Astronomy. Retrieved 2014-12-09.
  9. ^ "Caltech Astronomy - The 18-inch Schmidt Telescope". Caltech Astronomy. Retrieved 2014-12-09.
  10. ^ "Caltech Astronomy - Palomar Testbed Interferometer (PTI)". Caltech Astronomy. Retrieved 2014-12-09.
  11. ^ "Caltech Astronomy - Sleuth: The Palomar Planet Finder". Palomar Skies. Retrieved 2014-12-09.
  12. ^ Caltech did recognize Fritz Zwicky's sky survey pioneering work; however, The Big Picture project failed to recognize his contribution to the sky survey technique in the introductory panel at the Griffith Observatory.
  13. ^ Minnesota Automated Plate Scanner (MAPS): MAPS catalogue; Mollise, Rod. (2006). The Urban Astronomer's Guide: a Walking tour of the Cosmos for City Sky Watchers, p. 238., p. 238, at Google Books
  14. ^ Caltech: The Second Palomar Observatory Sky Survey (POSS-II)
  15. ^ NASA/Space Telescope Science Institute (STScI).: Multimission Archive at STScI (MAST)
  16. ^ Caltech press release: "New Sky Survey Begins at Palomar Observatory." July 29, 2003.
  17. ^ Caltech: "The Big Picture"
  18. ^ JPL: "Planet-Hunting Method Succeeds at Last." May 28, 2009.
  19. ^ Caltech: Hale Telescope Observing Runs
  20. ^ Caltech: Palomar Transient Factory (PTF)
  21. ^ Ghosh, Pallab. "'Clearest' images taken of space," BBC. September 3, 2007; University of Cambridge, Institute of Astronomy, Lucky Imaging website
  22. ^ Reuben H. Fleet Science Center: Palomar Observatory tour
  23. ^ [1]
  24. ^ Biography of George Ellery Hale at scienceworld.wolfram.com

Further reading