Telescope

A telescope is a device used to observe distant objects by their emission, absorption, or reflection of electromagnetic radiation.[1] Originally meaning only an optical instrument using lenses, curved mirrors, or a combination of both to observe distant objects, the word telescope now refers to a wide range of instruments capable of detecting different regions of the electromagnetic spectrum, and in some cases other types of detectors.

The 100-inch (2.54 m) Hooker reflecting telescope at Mount Wilson Observatory near Los Angeles, USA, used by Edwin Hubble to measure galaxy redshifts and discover the general expansion of the universe.

The first known practical telescopes were refracting telescopes with glass lenses and were invented in the Netherlands at the beginning of the 17th century. They were used for both terrestrial applications and astronomy.

The reflecting telescope, which uses mirrors to collect and focus light, was invented within a few decades of the first refracting telescope.

In the 20th century, many new types of telescopes were invented, including radio telescopes in the 1930s and infrared telescopes in the 1960s.

Etymology

The word telescope was coined in 1611 by the Greek mathematician Giovanni Demisiani for one of Galileo Galilei's instruments presented at a banquet at the Accademia dei Lincei.[2][3] In the Starry Messenger, Galileo had used the Latin term perspicillum. The root of the word is from the Ancient Greek τῆλε, romanized tele 'far' and σκοπεῖν, skopein 'to look or see'; τηλεσκόπος, teleskopos 'far-seeing'.[4]

History

17th century telescope

The earliest existing record of a telescope was a 1608 patent submitted to the government in the Netherlands by Middelburg spectacle maker Hans Lipperhey for a refracting telescope.[5] The actual inventor is unknown but word of it spread through Europe. Galileo heard about it and, in 1609, built his own version, and made his telescopic observations of celestial objects.[6][7]

The idea that the objective, or light-gathering element, could be a mirror instead of a lens was being investigated soon after the invention of the refracting telescope.[8] The potential advantages of using parabolic mirrors—reduction of spherical aberration and no chromatic aberration—led to many proposed designs and several attempts to build reflecting telescopes.[9] In 1668, Isaac Newton built the first practical reflecting telescope, of a design which now bears his name, the Newtonian reflector.[10]

The invention of the achromatic lens in 1733 partially corrected color aberrations present in the simple lens[11] and enabled the construction of shorter, more functional refracting telescopes. Reflecting telescopes, though not limited by the color problems seen in refractors, were hampered by the use of fast tarnishing speculum metal mirrors employed during the 18th and early 19th century—a problem alleviated by the introduction of silver coated glass mirrors in 1857, and aluminized mirrors in 1932.[12] The maximum physical size limit for refracting telescopes is about 1 meter (39 inches), dictating that the vast majority of large optical researching telescopes built since the turn of the 20th century have been reflectors. The largest reflecting telescopes currently have objectives larger than 10 meters (33 feet), and work is underway on several 30-40m designs.[13]

The 20th century also saw the development of telescopes that worked in a wide range of wavelengths from radio to gamma-rays. The first purpose-built radio telescope went into operation in 1937. Since then, a large variety of complex astronomical instruments have been developed.

In space

Since the atmosphere is opaque for most of the electromagnetic spectrum, only a few bands can be observed from the Earth's surface. These bands are visible – near-infrared and a portion of the radio-wave part of the spectrum.[14] For this reason there are no X-ray or far-infrared ground-based telescopes as these have to be observed from orbit. Even if a wavelength is observable from the ground, it might still be advantageous to place a telescope on a satellite due to issues such as clouds, astronomical seeing and light pollution.[15]

The disadvantages of launching a space telescope include cost, size, maintainability and upgradability.[16]

By electromagnetic spectrum

Six views of the Crab Nebula at different wavelengths of light

The name "telescope" covers a wide range of instruments. Most detect electromagnetic radiation, but there are major differences in how astronomers must go about collecting light (electromagnetic radiation) in different frequency bands.

As wavelengths become longer, it becomes easier to use antenna technology to interact with electromagnetic radiation (although it is possible to make very tiny antenna). The near-infrared can be collected much like visible light, however in the far-infrared and submillimetre range, telescopes can operate more like a radio telescope. For example, the James Clerk Maxwell Telescope observes from wavelengths from 3 μm (0.003 mm) to 2000 μm (2 mm), but uses a parabolic aluminum antenna.[17] On the other hand, the Spitzer Space Telescope, observing from about 3 μm (0.003 mm) to 180 μm (0.18 mm) uses a mirror (reflecting optics). Also using reflecting optics, the Hubble Space Telescope with Wide Field Camera 3 can observe in the frequency range from about 0.2 μm (0.0002 mm) to 1.7 μm (0.0017 mm) (from ultra-violet to infrared light).[18]

With photons of the shorter wavelengths, with the higher frequencies, glancing-incident optics, rather than fully reflecting optics are used. Telescopes such as TRACE and SOHO use special mirrors to reflect extreme ultraviolet, producing higher resolution and brighter images than are otherwise possible. A larger aperture does not just mean that more light is collected, it also enables a finer angular resolution.

Telescopes may also be classified by location: ground telescope, space telescope, or flying telescope. They may also be classified by whether they are operated by professional astronomers or amateur astronomers. A vehicle or permanent campus containing one or more telescopes or other instruments is called an observatory.

Radio and submilimeter

Three radio telescopes belonging to the Atacama Large Millimeter Array

Radio telescopes are directional radio antennas that typically employ a large dish to collect radio waves. The dishes are sometimes constructed of a conductive wire mesh whose openings are smaller than the wavelength being observed.

Unlike an optical telescope, which produces a magnified image of the patch of sky being observed, a traditional radio telescope dish contains a single receiver and records a single time-varying signal characteristic of the observed region; this signal may be sampled at various frequencies. In some newer radio telescope designs, a single dish contains an array of several receivers; this is known as a focal-plane array.

By collecting and correlating signals simultaneously received by several dishes, high-resolution images can be computed. Such multi-dish arrays are known as astronomical interferometers and the technique is called aperture synthesis. The 'virtual' apertures of these arrays are similar in size to the distance between the telescopes. As of 2005, the record array size is many times the diameter of the Earth – using space-based very-long-baseline-interferometry (VLBI) telescopes such as the Japanese HALCA (Highly Advanced Laboratory for Communications and Astronomy) VSOP (VLBI Space Observatory Program) satellite.[19]

Aperture synthesis is now also being applied to optical telescopes using optical interferometers (arrays of optical telescopes) and aperture masking interferometry at single reflecting telescopes.

Radio telescopes are also used to collect microwave radiation, which has the advantage of being able to pass through the atmosphere and interstellar gas and dust clouds.

Some radio telescopes such as the Allen Telescope Array are used by programs such as SETI[20] and the Arecibo Observatory to search for extraterrestrial life.[21][22]

Infrared

Visible light

One of four auxiliary telescopes belong to the Very Large Telescope array

An optical telescope gathers and focuses light mainly from the visible part of the electromagnetic spectrum.[23] Optical telescopes increase the apparent angular size of distant objects as well as their apparent brightness. For the image to be observed, photographed, studied, and sent to a computer, telescopes work by employing one or more curved optical elements, usually made from glass lenses and/or mirrors, to gather light and other electromagnetic radiation to bring that light or radiation to a focal point. Optical telescopes are used for astronomy and in many non-astronomical instruments, including: theodolites (including transits), spotting scopes, monoculars, binoculars, camera lenses, and spyglasses. There are three main optical types:

A Fresnel imager is a proposed ultra-lightweight design for a space telescope that uses a Fresnel lens to focus light.[26][27]

Beyond these basic optical types there are many sub-types of varying optical design classified by the task they perform such as astrographs,[28] comet seekers[29] and solar telescopes.[30]

Ultraviolet

Most ultraviolet light is absorbed by the Earth's atmosphere, so observations at these wavelengths must be performed from the upper atmosphere or from space.[31][32]

X-ray

Hitomi telescope's X-ray focusing mirror, consisting of over two hundred concentric aluminium shells

X-rays are much harder to collect and focus than electromagnetic radiation of longer wavelengths. X-ray telescopes can use X-ray optics, such as Wolter telescopes composed of ring-shaped 'glancing' mirrors made of heavy metals that are able to reflect the rays just a few degrees. The mirrors are usually a section of a rotated parabola and a hyperbola, or ellipse. In 1952, Hans Wolter outlined 3 ways a telescope could be built using only this kind of mirror.[33][34] Examples of space observatories using this type of telescope are the Einstein Observatory,[35] ROSAT,[36] and the Chandra X-ray Observatory.[37][38] In 2012 the NuSTAR X-ray Telescope was launched which uses Wolter telescope design optics at the end of a long deployable mast to enable photon energies of 79 keV.[39][40]

Gamma ray

The Compton Gamma Ray Observatory released into orbit by the Space Shuttle in 1991

Higher energy X-ray and gamma ray telescopes refrain from focusing completely and use coded aperture masks: the patterns of the shadow the mask creates can be reconstructed to form an image.

X-ray and Gamma-ray telescopes are usually installed on high-flying balloons[41][42] or Earth-orbiting satellites since the Earth's atmosphere is opaque to this part of the electromagnetic spectrum. An example of this type of telescope is the Fermi Gamma-ray Space Telescope which was launched in June 2008.[43][44]

The detection of very high energy gamma rays, with shorter wavelength and higher frequency than regular gamma rays, requires further specialization. An example of this type of observatory is the ground based telescope VERITAS.[45][46]

A discovery in 2012 may allow focusing gamma-ray telescopes.[47] At photon energies greater than 700 keV, the index of refraction starts to increase again.[47]

Lists of telescopes

  • List of optical telescopes
  • List of largest optical reflecting telescopes
  • List of largest optical refracting telescopes
  • List of largest optical telescopes historically
  • List of radio telescopes
  • List of solar telescopes
  • List of space observatories
  • List of telescope parts and construction
  • List of telescope types

See also

  • Airmass
  • Amateur telescope making
  • Angular resolution
  • ASCOM open standards for computer control of telescopes
  • Bahtinov mask
  • Bioptic telescope
  • Carey mask
  • Dew shield
  • Dynameter
  • f-number
  • First light
  • Hartmann mask
  • Keyhole problem
  • Microscope
  • Planetariums
  • Remote Telescope Markup Language
  • Robotic telescope
  • Timeline of telescope technology
  • Timeline of telescopes, observatories, and observing technology

References

  1. Company, Houghton Mifflin Harcourt Publishing. "The American Heritage Dictionary entry: TELESCOPE". www.ahdictionary.com. Archived from the original on 11 March 2020. Retrieved 12 July 2018.
  2. Sobel (2000, p.43), Drake (1978, p.196)
  3. Rosen, Edward, The Naming of the Telescope (1947)
  4. Jack, Albert (2015). They Laughed at Galileo: How the Great Inventors Proved Their Critics Wrong. ISBN 978-1629147581.
  5. galileo.rice.edu The Galileo Project > Science > The Telescope by Al Van Helden: The Hague discussed the patent applications first of Hans Lipperhey of Middelburg, and then of Archived 23 June 2004 at the Wayback MachineJacob Metius of Alkmaar... another citizen of Middelburg, Zacharias Janssen is sometimes associated with the invention
  6. "NASA – Telescope History". www.nasa.gov. Archived from the original on 14 February 2021. Retrieved 11 July 2017.
  7. Loker, Aleck (20 November 2017). Profiles in Colonial History. Aleck Loker. ISBN 978-1-928874-16-4. Archived from the original on 27 May 2016. Retrieved 12 December 2015 via Google Books.
  8. Watson, Fred (20 November 2017). Stargazer: The Life and Times of the Telescope. Allen & Unwin. ISBN 978-1-74176-392-8. Archived from the original on 2 March 2021. Retrieved 21 November 2020 via Google Books.
  9. Attempts by Niccolò Zucchi and James Gregory and theoretical designs by Bonaventura Cavalieri, Marin Mersenne, and Gregory among others
  10. Hall, A. Rupert (1992). Isaac Newton: Adventurer in Thought. Cambridge University Press. p. 67. ISBN 9780521566698.
  11. "Chester Moor Hall". Encyclopædia Britannica. Retrieved 25 May 2016.
  12. Bakich, Michael E. (10 July 2003). "Chapter Two: Equipment". The Cambridge Encyclopedia of Amateur Astronomy (PDF). Cambridge University Press. p. 33. ISBN 9780521812986. Archived from the original (PDF) on 10 September 2009.
  13. Tate, Karl (30 August 2013). "World's Largest Reflecting Telescopes Explained (Infographic)". Space.com.
  14. Stierwalt, Everyday Einstein Sabrina. "Why Do We Put Telescopes in Space?". Scientific American. Retrieved 20 August 2022.
  15. Siegel, Ethan. "5 Reasons Why Astronomy Is Better From The Ground Than In Space". Forbes. Retrieved 20 August 2022.
  16. Siegel, Ethan. "This Is Why We Can't Just Do All Of Our Astronomy From Space". Forbes. Retrieved 20 August 2022.
  17. ASTROLab du parc national du Mont-Mégantic (January 2016). "The James-Clerk-Maxwell Observatory". Canada under the stars. Archived from the original on 5 February 2011. Retrieved 16 April 2017.
  18. "Hubble's Instruments: WFC3 – Wide Field Camera 3". www.spacetelescope.org. Archived from the original on 12 November 2020. Retrieved 16 April 2017.
  19. "Observatories Across the Electromagnetic Spectrum". imagine.gsfc.nasa.gov. Retrieved 20 August 2022.
  20. Dalton, Rex (1 August 2000). "Microsoft moguls back search for ET intelligence". Nature. 406 (6796): 551. doi:10.1038/35020722. ISSN 1476-4687. PMID 10949267. S2CID 4415108.
  21. Tarter, Jill (September 2001). "The Search for Extraterrestrial Intelligence (SETI)". Annual Review of Astronomy and Astrophysics. 39 (1): 511–548. Bibcode:2001ARA&A..39..511T. doi:10.1146/annurev.astro.39.1.511. ISSN 0066-4146. Archived from the original on 20 August 2022. Retrieved 20 August 2022.
  22. Nola Taylor Tillman (2 August 2016). "SETI & the Search for Extraterrestrial Life". Space.com. Retrieved 20 August 2022.
  23. Jones, Barrie W. (2 September 2008). The Search for Life Continued: Planets Around Other Stars. Springer Science & Business Media. ISBN 978-0-387-76559-4. Archived from the original on 8 March 2020. Retrieved 12 December 2015.
  24. Lauren Cox (26 October 2021). "Who Invented the Telescope?". Space.com. Retrieved 20 August 2022.
  25. Rupert, Charles G. (1918). "1918PA.....26..525R Page 525". Popular Astronomy. 26: 525. Bibcode:1918PA.....26..525R. Retrieved 20 August 2022.
  26. "Telescope could focus light without a mirror or lens". New Scientist. Retrieved 20 August 2022.
  27. Koechlin, L.; Serre, D.; Duchon, P. (1 November 2005). "High resolution imaging with Fresnel interferometric arrays: suitability for exoplanet detection". Astronomy & Astrophysics. 443 (2): 709–720. arXiv:astro-ph/0510383. Bibcode:2005A&A...443..709K. doi:10.1051/0004-6361:20052880. ISSN 0004-6361. S2CID 119423063.
  28. "Celestron Rowe-Ackermann Schmidt Astrograph – Astronomy Now". Retrieved 20 August 2022.
  29. "Telescope (Comet Seeker)". Smithsonian Institution. Retrieved 20 August 2022.
  30. Stenflo, J. O. (1 January 2001). "Limitations and Opportunities for the Diagnostics of Solar and Stellar Magnetic Fields". Magnetic Fields Across the Hertzsprung-Russell Diagram. 248: 639. Bibcode:2001ASPC..248..639S.
  31. Allen, C. W. (2000). Allen's astrophysical quantities. Arthur N. Cox (4th ed.). New York: AIP Press. ISBN 0-387-98746-0. OCLC 40473741.
  32. Ortiz, Roberto; Guerrero, Martín A. (28 June 2016). "Ultraviolet emission from main-sequence companions of AGB stars". Monthly Notices of the Royal Astronomical Society. 461 (3): 3036–3046. doi:10.1093/mnras/stw1547. ISSN 0035-8711.
  33. Wolter, H. (1952), "Glancing Incidence Mirror Systems as Imaging Optics for X-rays", Annalen der Physik, 10 (1): 94–114, Bibcode:1952AnP...445...94W, doi:10.1002/andp.19524450108.
  34. Wolter, H. (1952), "Verallgemeinerte Schwarzschildsche Spiegelsysteme streifender Reflexion als Optiken für Röntgenstrahlen", Annalen der Physik, 10 (4–5): 286–295, Bibcode:1952AnP...445..286W, doi:10.1002/andp.19524450410.
  35. Giacconi, R.; Branduardi, G.; Briel, U.; Epstein, A.; Fabricant, D.; Feigelson, E.; Forman, W.; Gorenstein, P.; Grindlay, J.; Gursky, H.; Harnden, F. R.; Henry, J. P.; Jones, C.; Kellogg, E.; Koch, D. (June 1979). "The Einstein /HEAO 2/ X-ray Observatory". The Astrophysical Journal. 230: 540. Bibcode:1979ApJ...230..540G. doi:10.1086/157110. ISSN 0004-637X.
  36. "DLR - About the ROSAT mission". DLRARTICLE DLR Portal. Retrieved 20 August 2022.
  37. Schwartz, Daniel A. (1 August 2004). "The development and scientific impact of the chandra x-ray observatory". International Journal of Modern Physics D. 13 (7): 1239–1247. arXiv:astro-ph/0402275. Bibcode:2004IJMPD..13.1239S. doi:10.1142/S0218271804005377. ISSN 0218-2718. S2CID 858689.
  38. Madejski, Greg (2006). "Recent and Future Observations in the X‐ray and Gamma‐ray Bands: Chandra, Suzaku, GLAST, and NuSTAR". AIP Conference Proceedings. 801 (1): 21–30. arXiv:astro-ph/0512012. Bibcode:2005AIPC..801...21M. doi:10.1063/1.2141828. ISSN 0094-243X. S2CID 14601312.
  39. "NuStar: Instrumentation: Optics". Archived from the original on 1 November 2010.
  40. Hailey, Charles J.; An, HongJun; Blaedel, Kenneth L.; Brejnholt, Nicolai F.; Christensen, Finn E.; Craig, William W.; Decker, Todd A.; Doll, Melanie; Gum, Jeff; Koglin, Jason E.; Jensen, Carsten P.; Hale, Layton; Mori, Kaya; Pivovaroff, Michael J.; Sharpe, Marton (29 July 2010). Arnaud, Monique; Murray, Stephen S; Takahashi, Tadayuki (eds.). "The Nuclear Spectroscopic Telescope Array (NuSTAR): optics overview and current status". Space Telescopes and Instrumentation 2010: Ultraviolet to Gamma Ray. SPIE. 7732: 197–209. Bibcode:2010SPIE.7732E..0TH. doi:10.1117/12.857654. S2CID 121831705.
  41. Braga, João; D’Amico, Flavio; Avila, Manuel A. C.; Penacchioni, Ana V.; Sacahui, J. Rodrigo; Santiago, Valdivino A. de; Mattiello-Francisco, Fátima; Strauss, Cesar; Fialho, Márcio A. A. (1 August 2015). "The protoMIRAX hard X-ray imaging balloon experiment". Astronomy & Astrophysics. 580: A108. arXiv:1505.06631. Bibcode:2015A&A...580A.108B. doi:10.1051/0004-6361/201526343. ISSN 0004-6361. S2CID 119222297.
  42. Brett Tingley (13 July 2022). "Balloon-borne telescope lifts off to study black holes and neutron stars". Space.com. Retrieved 20 August 2022.
  43. Atwood, W. B.; Abdo, A. A.; Ackermann, M.; Althouse, W.; Anderson, B.; Axelsson, M.; Baldini, L.; Ballet, J.; Band, D. L.; Barbiellini, G.; Bartelt, J.; Bastieri, D.; Baughman, B. M.; Bechtol, K.; Bédérède, D. (1 June 2009). "The Large Area Telescope on Thefermi Gamma-Ray Space Telescopemission". The Astrophysical Journal. 697 (2): 1071–1102. arXiv:0902.1089. Bibcode:2009ApJ...697.1071A. doi:10.1088/0004-637X/697/2/1071. ISSN 0004-637X. S2CID 26361978.
  44. Ackermann, M.; Ajello, M.; Baldini, L.; Ballet, J.; Barbiellini, G.; Bastieri, D.; Bellazzini, R.; Bissaldi, E.; Bloom, E. D.; Bonino, R.; Bottacini, E.; Brandt, T. J.; Bregeon, J.; Bruel, P.; Buehler, R. (13 July 2017). "Search for Extended Sources in the Galactic Plane Using Six Years ofFermi-Large Area Telescope Pass 8 Data above 10 GeV". The Astrophysical Journal. 843 (2): 139. arXiv:1702.00476. Bibcode:2017ApJ...843..139A. doi:10.3847/1538-4357/aa775a. ISSN 1538-4357. S2CID 119187437.
  45. Krennrich, F.; Bond, I. H.; Boyle, P. J.; Bradbury, S. M.; Buckley, J. H.; Carter-Lewis, D.; Celik, O.; Cui, W.; Daniel, M.; D'Vali, M.; de la Calle Perez, I.; Duke, C.; Falcone, A.; Fegan, D. J.; Fegan, S. J. (1 April 2004). "VERITAS: the Very Energetic Radiation Imaging Telescope Array System". New Astronomy Reviews. 2nd VERITAS Symposium on the Astrophysics of Extragalactic Sources. 48 (5): 345–349. Bibcode:2004NewAR..48..345K. doi:10.1016/j.newar.2003.12.050. hdl:10379/9414. ISSN 1387-6473.
  46. Weekes, T. C.; Cawley, M. F.; Fegan, D. J.; Gibbs, K. G.; Hillas, A. M.; Kowk, P. W.; Lamb, R. C.; Lewis, D. A.; Macomb, D.; Porter, N. A.; Reynolds, P. T.; Vacanti, G. (1 July 1989). "Observation of TeV Gamma Rays from the Crab Nebula Using the Atmospheric Cerenkov Imaging Technique". The Astrophysical Journal. 342: 379. Bibcode:1989ApJ...342..379W. doi:10.1086/167599. ISSN 0004-637X. S2CID 119424766.
  47. "Silicon 'prism' bends gamma rays – Physics World". 9 May 2012. Archived from the original on 12 May 2013. Retrieved 15 May 2012.

Further reading

This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.