Redaktor:Masleyko/pieskovisko

Etymology

The word "star" ultimately derives from the Proto-Indo-European root "h₂stḗr" also meaning star, but further analyzable as h₂eh₁s- ("to burn", also the source of the word "ash") + -tēr (agentive suffix). Compare Latin stella, Greek aster, German Stern. Some scholars believe the word is a borrowing from Akkadian "istar" (venus), however some doubt that suggestion. Star is cognate (shares the same root) with the following words: asterisk, asteroid, astral, constellation, Esther.^[1]

Observation history

Šablóna:Seealso

 

People have interpreted patterns and images in the stars since ancient times.^[2] This 1690 depiction of the constellation of Leo, the lion, is by Johannes Hevelius.^[3]

Historically, stars have been important to civilizations throughout the world. They have been part of religious practices, used for celestial navigation and orientation, to mark the passage of seasons, and to define calendars.

Early astronomers recognized a difference between "fixed stars", whose position on the celestial sphere does not change, and "wandering stars" (planets), which move noticeably relative to the fixed stars over days or weeks.^[4] Many ancient astronomers believed that the stars were permanently affixed to a heavenly sphere and that they were immutable. By convention, astronomers grouped prominent stars into asterisms and constellations and used them to track the motions of the planets and the inferred position of the Sun.^[2] The motion of the Sun against the background stars (and the horizon) was used to create calendars, which could be used to regulate agricultural practices.^[5] The Gregorian calendar, currently used nearly everywhere in the world, is a solar calendar based on the angle of the Earth's rotational axis relative to its local star, the Sun.

The oldest accurately dated star chart was the result of ancient Egyptian astronomy in 1534 BC.^[6] The earliest known star catalogues were compiled by the ancient Babylonian astronomers of Mesopotamia in the late 2nd millennium BC, during the Kassite Period (Šablóna:Circa).^[7]

 

Stars in the night sky

The first star catalogue in Greek astronomy was created by Aristillus in approximately 300 BC, with the help of Timocharis.^[8] The star catalog of Hipparchus (2nd century BC) included 1,020 stars, and was used to assemble Ptolemy's star catalogue.^[9] Hipparchus is known for the discovery of the first recorded nova (new star).^[10] Many of the constellations and star names in use today derive from Greek astronomy.

Despite the apparent immutability of the heavens, Chinese astronomers were aware that new stars could appear.^[11] In 185 AD, they were the first to observe and write about a supernova, now known as SN 185.^[12] The brightest stellar event in recorded history was the SN 1006 supernova, which was observed in 1006 and written about by the Egyptian astronomer Ali ibn Ridwan and several Chinese astronomers.^[13] The SN 1054 supernova, which gave birth to the Crab Nebula, was also observed by Chinese and Islamic astronomers.^[14][15][16]

Medieval Islamic astronomers gave Arabic names to many stars that are still used today and they invented numerous astronomical instruments that could compute the positions of the stars. They built the first large observatory research institutes, mainly to produce Zij star catalogues.^[17] Among these, the Book of Fixed Stars (964) was written by the Persian astronomer Abd al-Rahman al-Sufi, who observed a number of stars, star clusters (including the Omicron Velorum and Brocchi's Clusters) and galaxies (including the Andromeda Galaxy).^[18] According to A. Zahoor, in the 11th century, the Persian polymath scholar Abu Rayhan Biruni described the Milky Way galaxy as a multitude of fragments having the properties of nebulous stars, and gave the latitudes of various stars during a lunar eclipse in 1019.^[19]

According to Josep Puig, the Andalusian astronomer Ibn Bajjah proposed that the Milky Way was made up of many stars that almost touched one another and appeared to be a continuous image due to the effect of refraction from sublunary material, citing his observation of the conjunction of Jupiter and Mars on 500 AH (1106/1107 AD) as evidence.^[20] Early European astronomers such as Tycho Brahe identified new stars in the night sky (later termed novae), suggesting that the heavens were not immutable. In 1584, Giordano Bruno suggested that the stars were like the Sun, and may have other planets, possibly even Earth-like, in orbit around them,^[21] an idea that had been suggested earlier by the ancient Greek philosophers, Democritus and Epicurus,^[22] and by medieval Islamic cosmologists^[23] such as Fakhr al-Din al-Razi.^[24] By the following century, the idea of the stars being the same as the Sun was reaching a consensus among astronomers. To explain why these stars exerted no net gravitational pull on the Solar System, Isaac Newton suggested that the stars were equally distributed in every direction, an idea prompted by the theologian Richard Bentley.^[25]

The Italian astronomer Geminiano Montanari recorded observing variations in luminosity of the star Algol in 1667. Edmond Halley published the first measurements of the proper motion of a pair of nearby "fixed" stars, demonstrating that they had changed positions since the time of the ancient Greek astronomers Ptolemy and Hipparchus.^[21]

William Herschel was the first astronomer to attempt to determine the distribution of stars in the sky. During the 1780s, he established a series of gauges in 600 directions and counted the stars observed along each line of sight. From this, he deduced that the number of stars steadily increased toward one side of the sky, in the direction of the Milky Way core. His son John Herschel repeated this study in the southern hemisphere and found a corresponding increase in the same direction.^[26] In addition to his other accomplishments, William Herschel is noted for his discovery that some stars do not merely lie along the same line of sight, but are physical companions that form binary star systems.^[27]

The science of stellar spectroscopy was pioneered by Joseph von Fraunhofer and Angelo Secchi. By comparing the spectra of stars such as Sirius to the Sun, they found differences in the strength and number of their absorption lines—the dark lines in stellar spectra caused by the atmosphere's absorption of specific frequencies. In 1865, Secchi began classifying stars into spectral types.^[28] The modern version of the stellar classification scheme was developed by Annie J. Cannon during the early 1900s.^[29]

The first direct measurement of the distance to a star (61 Cygni at 11.4 light-years) was made in 1838 by Friedrich Bessel using the parallax technique. Parallax measurements demonstrated the vast separation of the stars in the heavens.^[21] Observation of double stars gained increasing importance during the 19th century. In 1834, Friedrich Bessel observed changes in the proper motion of the star Sirius and inferred a hidden companion. Edward Pickering discovered the first spectroscopic binary in 1899 when he observed the periodic splitting of the spectral lines of the star Mizar in a 104-day period. Detailed observations of many binary star systems were collected by astronomers such as Friedrich Georg Wilhelm von Struve and S. W. Burnham, allowing the masses of stars to be determined from computation of orbital elements. The first solution to the problem of deriving an orbit of binary stars from telescope observations was made by Felix Savary in 1827.^[30]

The twentieth century saw increasingly rapid advances in the scientific study of stars. The photograph became a valuable astronomical tool. Karl Schwarzschild discovered that the color of a star and, hence, its temperature, could be determined by comparing the visual magnitude against the photographic magnitude. The development of the photoelectric photometer allowed precise measurements of magnitude at multiple wavelength intervals. In 1921 Albert A. Michelson made the first measurements of a stellar diameter using an interferometer on the Hooker telescope at Mount Wilson Observatory.^[31]

Important theoretical work on the physical structure of stars occurred during the first decades of the twentieth century. In 1913, the Hertzsprung-Russell diagram was developed, propelling the astrophysical study of stars. Successful models were developed to explain the interiors of stars and stellar evolution. Cecilia Payne-Gaposchkin first proposed that stars were made primarily of hydrogen and helium in her 1925 PhD thesis.^[32] The spectra of stars were further understood through advances in quantum physics. This allowed the chemical composition of the stellar atmosphere to be determined.^[33]

 

Infrared image from NASA's Spitzer Space Telescope showing hundreds of thousands of stars in the Milky Way galaxy

With the exception of rare events such as supernovae and supernova imposters, individual stars have primarily been observed in the Local Group,^[34] and especially in the visible part of the Milky Way (as demonstrated by the detailed star catalogues available for the Milky Way galaxy) and its satellites.^[35] Individual stars such as Cepheid variables have been observed in the M87^[36] and M100 galaxies of the Virgo Cluster,^[37] as well as luminous stars in some other relatively nearby galaxies.^[38] With the aid of gravitational lensing, a single star (named Icarus) has been observed at 9 billion light-years away.^[39][40]

Designations

Bližšie informácie v článkoch: Stellar designation, Astronomical naming conventions a Star catalogue

The concept of a constellation was known to exist during the Babylonian period. Ancient sky watchers imagined that prominent arrangements of stars formed patterns, and they associated these with particular aspects of nature or their myths. Twelve of these formations lay along the band of the ecliptic and these became the basis of astrology.^[41] Many of the more prominent individual stars were given names, particularly with Arabic or Latin designations.

As well as certain constellations and the Sun itself, individual stars have their own myths.^[42] To the Ancient Greeks, some "stars", known as planets (Greek πλανήτης (planētēs), meaning "wanderer"), represented various important deities, from which the names of the planets Mercury, Venus, Mars, Jupiter and Saturn were taken.^[42] (Uranus and Neptune were Greek and Roman gods, but neither planet was known in Antiquity because of their low brightness. Their names were assigned by later astronomers.)

Circa 1600, the names of the constellations were used to name the stars in the corresponding regions of the sky. The German astronomer Johann Bayer created a series of star maps and applied Greek letters as designations to the stars in each constellation. Later a numbering system based on the star's right ascension was invented and added to John Flamsteed's star catalogue in his book "Historia coelestis Britannica" (the 1712 edition), whereby this numbering system came to be called Flamsteed designation or Flamsteed numbering.^[43][44]

The internationally recognized authority for naming celestial bodies is the International Astronomical Union (IAU).^[45] The International Astronomical Union maintains the Working Group on Star Names (WGSN)^[46] which catalogs and standardizes proper names for stars.^[47] A number of private companies sell names of stars which are not recognized by the IAU, professional astronomers, or the amateur astronomy community.^[48] The British Library calls this an unregulated commercial enterprise,^[49][50] and the New York City Department of Consumer and Worker Protection issued a violation against one such star-naming company for engaging in a deceptive trade practice.^[51][52]

1. HARPER, Douglas.
   • ster- (2) [online]. 2001–2022. Dostupné online.
2. FORBES, George. History of Astronomy. London : Watts & Co., 1909. Dostupné online. ISBN 978-1-153-62774-0.
3. HEVELIUS, Johannis. Firmamentum Sobiescianum, sive Uranographia. Gdansk : [s.n.], 1690.
4. Ancient Greek Astronomy and Cosmology [online]. The Library of Congress, n.d.. Dostupné online.
5. TØNDERING, Claus. Other Ancient Calendars [online]. Webexhibits, 2008. Dostupné online.
6. VON SPAETH, Ove. Dating the Oldest Egyptian Star Map. Centaurus, 2000, s. 159–179. Dostupné online [cit. 2007-10-21]. DOI: 10.1034/j.1600-0498.2000.420301.x.
7. NORTH, John. The Norton History of Astronomy and Cosmology. New York and London : W.W. Norton & Company, 1995. Dostupné online. ISBN 978-0-393-03656-5. S. 30–31.
8. MURDIN, P.. Encyclopedia of Astronomy and Astrophysics. [s.l.] : [s.n.], 2000. ISBN 978-0-333-75088-9. DOI:10.1888/0333750888/3440 Aristillus (c. 200 BC).
9. GRASSHOFF, Gerd. The history of Ptolemy's star catalogue. [s.l.] : Springer, 1990. ISBN 978-0-387-97181-0. S. 1–5.
10. PINOTSIS, Antonios D.. Astronomy in Ancient Rhodes [online]. University of Athens, Greece, 2008. Dostupné online. Archivované 2021-09-07 z originálu.
11. Clark, D. H.; Stephenson, F. R. (1981-06-29). "The Historical Supernovae". Supernovae: A survey of current research; Proceedings of the Advanced Study Institute. Cambridge, UK: Dordrecht, D. Reidel Publishing Co. pp. 355–370. Bibcode:1982ASIC...90..355C.
12. The Guest Star of AD185 must have been a Supernova. Chinese Journal of Astronomy and Astrophysics, 2006, s. 635. DOI: 10.1088/1009-9271/6/5/17.
13. Astronomers Peg Brightness of History's Brightest Star [online]. National Optical Astronomy Observatory, 5 March 2003. Dostupné online. Archivované 2003-04-02 z originálu.
14. Supernova 1054 – Creation of the Crab Nebula [online]. University of Arizona, 2006-08-30. Dostupné online.
15. DUYVENDAK, J. J. L.. Further Data Bearing on the Identification of the Crab Nebula with the Supernova of 1054 A.D. Part I. The Ancient Oriental Chronicles. Publications of the Astronomical Society of the Pacific, April 1942, s. 91–94. DOI: 10.1086/125409.
    Further Data Bearing on the Identification of the Crab Nebula with the Supernova of 1054 A.D. Part II. The Astronomical Aspects. Publications of the Astronomical Society of the Pacific, April 1942, s. 95–104. DOI: 10.1086/125410.
16. Ancient records and the Crab Nebula supernova. The Observatory, 1983, s. 106–113.
17. KENNEDY, Edward S.. Review: The Observatory in Islam and Its Place in the General History of the Observatory by Aydin Sayili. Isis, 1962, s. 237–239. DOI: 10.1086/349558.
18. JONES, Kenneth Glyn. Messier's nebulae and star clusters. [s.l.] : Cambridge University Press, 1991. Dostupné online. ISBN 978-0-521-37079-0. S. 1.
19. ZAHOOR, A.. Al-Biruni [online]. Hasanuddin University, 1997. Dostupné online. Archivované 2008-06-26 z originálu.
20. Šablóna:Cite encyclopedia
21. DRAKE, Stephen A.. A Brief History of High-Energy (X-ray & Gamma-Ray) Astronomy [online]. NASA HEASARC, 2006-08-17. Dostupné online.
22. Exoplanets [online]. ESO, 2006-07-24. Dostupné online. Archivované 2008-10-10 z originálu.
23. AHMAD, I. A.. The impact of the Qur'anic conception of astronomical phenomena on Islamic civilization. Vistas in Astronomy, 1995, s. 395–403 [402]. DOI: 10.1016/0083-6656(95)00033-X.
24. SETIA, Adi. Fakhr Al-Din Al-Razi on Physics and the Nature of the Physical World: A Preliminary Survey. Islam & Science, 2004. Dostupné online [cit. 2018-05-26].
25. HOSKIN, Michael. The Value of Archives in Writing the History of Astronomy. Library and Information Services in Astronomy III, 1998, s. 207. Dostupné online [cit. 2006-08-24].
26. PROCTOR, Richard A.. Are any of the nebulæ star-systems?. Nature, 1870, s. 331–333. Dostupné online. DOI: 10.1038/001331a0.
27. Frank Northen Magill. Magill's Survey of Science: A-Cherenkov detectors. [s.l.] : Salem Press, 1992. Dostupné online. ISBN 978-0-89356-619-7. S. 219.
28. MACDONNELL, Joseph. Angelo Secchi, S.J. (1818–1878) the Father of Astrophysics [online]. Fairfield University. Dostupné online. Archivované 2011-07-21 z originálu.
29. Ivan Hubeny; Dimitri Mihalas. Theory of Stellar Atmospheres: An Introduction to Astrophysical Non-equilibrium Quantitative Spectroscopic Analysis. [s.l.] : Princeton University Press, 2014. Dostupné online. ISBN 978-0-691-16329-1. S. 23.
30. AITKEN, Robert G.. The Binary Stars. New York : Dover Publications Inc., 1964. ISBN 978-0-486-61102-0. S. 66.
31. Measurement of the diameter of Alpha Orionis with the interferometer. Astrophysical Journal, 1921, s. 249–259. DOI: 10.1086/142603. PMID 16586823.
32. " Payne-Gaposchkin, Cecilia Helena." CWP [online]. University of California. Dostupné online. Archivované 2005-03-18 z originálu.
33. UNSÖLD, Albrecht. The New Cosmos. 5th. vyd. New York : Springer, 2001. ISBN 978-3-540-67877-9. S. 180–185, 215–216.
34. Luminous and Variable Stars in M31 and M33. III. The Yellow and Red Supergiants and Post-red Supergiant Evolution. The Astrophysical Journal, July 2016, s. 50. ISSN 0004-637X. DOI: 10.3847/0004-637X/825/1/50. (po anglicky)
35. Šablóna:Cite Gaia EDR3
36. Clustering of Local Group Distances: Publication Bias or Correlated Measurements? VI. Extending to Virgo Cluster Distances. The Astrophysical Journal Supplement Series, 2020, s. 3. DOI: 10.3847/1538-4365/ab5711.
37. Hubble Space Telescope Measures Precise Distance to the Most Remote Galaxy Yet [online]. Hubble Site, 1994-10-26. Dostupné online.
38. New luminous blue variable candidates in the NGC 247 galaxy. Monthly Notices of the Royal Astronomical Society, 2020, s. 4834. DOI: 10.1093/mnras/staa2117.
39. Kelly, Patrick L.. Extreme magnification of an individual star at redshift 1.5 by a galaxy-cluster lens. Nature, 2018-04-02, s. 334–342. DOI: 10.1038/s41550-018-0430-3.
40. HOWELL, Elizabeth. Rare Cosmic Alignment Reveals Most Distant Star Ever Seen [online]. 2018-04-02. Dostupné online.
41. Chyba citácie Neplatná značka <ref>; nebol zadaný text pre referencie s názvom koch95
42. COLEMAN, Leslie S. Myths, Legends and Lore [online]. Frosty Drew Observatory. Dostupné online.
43. Naming Astronomical Objects [online]. International Astronomical Union (IAU). Dostupné online.
44. Naming Stars [online]. Students for the Exploration and Development of Space (SEDS). Dostupné online.
45. Chyba citácie Neplatná značka <ref>; nebol zadaný text pre referencie s názvom space_law09
46. IAU Working Group on Star Names (WGSN) [online]. . Dostupné online.
47. Naming Stars [online]. . Dostupné online.
48. Chyba citácie Neplatná značka <ref>; nebol zadaný text pre referencie s názvom andersen10
49. Chyba citácie Neplatná značka <ref>; nebol zadaný text pre referencie s názvom astrometry05
50. Chyba citácie Neplatná značka <ref>; nebol zadaný text pre referencie s názvom bl_disclaimer
51. Chyba citácie Neplatná značka <ref>; nebol zadaný text pre referencie s názvom pliat02
52. Chyba citácie Neplatná značka <ref>; nebol zadaný text pre referencie s názvom sclafani19980508