3C 48

3C 48
3C 48
Observation data (Epoch J2000)
Constellation	Triangulum
Right ascension	01h 37m 41.1s
Declination	+33° 09′ 32″
Redshift	110,024 ± 0 km/s ; 0.367
Distance	3.9 billion light-years ; (Light travel time); 4.5 billion light-years; (present)
Type	E
Apparent dimensions (V)	0.6´X0.5´
Apparent magnitude (V)	16.2
Notable features	First quasar discovered
Other designations
	PG 0134+329, QSO B0134+329, PGC 73991
	See also: Quasar, List of quasars

Last updated December 13, 2024

3C48 is a quasar discovered in 1960; it was the second source conclusively identified as such.^[3]

3C48 was the first source in the Third Cambridge Catalogue of Radio Sources for which an optical identification was found by Allan Sandage and Thomas A. Matthews in 1960 through interferometry.^[4] In 1963 Jesse L. Greenstein and Thomas Matthews found that it had a redshift of 0.367, making it one of the highest redshift sources then known.^[5] It was not until 1982 that the surrounding faint galactic "nebulosity" was confirmed to have the same redshift as 3C48, cementing its identification as an object in a distant galaxy.^[6] This was also the first solid identification of a quasar with a surrounding galaxy at the same redshift.

3C 48 is one of four primary calibrators used by the Very Large Array (along with 3C 138 and 3C 147, and 3C 286). Visibilities of all other sources are calibrated using observed visibilities of one of these four calibrators.^[7]

Nomenclature

The name of the object “3C 48” consists of two significant parts. The first part, “3C,” means that the object belongs to the Third Cambridge Catalog of Radio Sources. The second part - “48” - is the serial number in the catalog ordered by right ascension.

History

3C 48 was the first source in the Third Cambridge Catalog of Radio Sources to be optically identified by Allan Sandage and Thomas Matthews in 1960 using interferometry.

Jesse Greenstein and Thomas Matthews found that it had a redshift of 0.367, one of the highest redshifts of any source known at the time. It was not until 1982 that a surrounding faint galactic "nebula" was measured to have the same redshift as 3C 48, confirming its identification as an object in a distant galaxy. This was also the first reliable identification of a quasar with a surrounding galaxy of the same redshift.^[8]

On September 26, 1960, Matthews and Sandage photographed an area of the sky containing one such source, 3C48, with the 200-inch telescope. To their surprise, there were no objects within the error rectangle of the coordinates in this area except for a star of 16.2^m. True, there were traces of a faint small nebula around it, but the object certainly looked like a star. Doubts about the possibility of identifying the radio source with a star disappeared on October 22, 1960, when Sandage obtained the spectrum of the object. It contained an unusual combination of broad emission lines that defied identification. The color indices of 3C48 were also unusual: Sandage found that they were consistent with hot white dwarfs and former Nova - very hot objects with an ultraviolet excess. In December 1960, Sandage reported the results of the first optical observations of 3C48 at the 107th meeting of the American Astronomical Society. Testing the hypothesis that 3C48 is a stellar remnant of a nova or even a supernova ("the first true radio star"), H. Smith and D. Hoffleit looked through the Harvard Sky Survey's collection of plates for 1897-1958 and did not find any noticeable fluctuations in the object's brightness exceeding 0.3m, which are common in former novae. The most likely possibility seemed to be that it was a neutron star - a remnant of a supernova.
— Yu. N. Efremov, Into the Universe, https://archive.org/details/isbn_535400392X_844

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3C 273 is a quasar located at the center of a giant elliptical galaxy in the constellation of Virgo. It was the first quasar ever to be identified and is the visually brightest quasar in the sky as seen from Earth, with an apparent visual magnitude of 12.9. The derived distance to this object is 749 megaparsecs. The mass of its central supermassive black hole is approximately 886 million times the mass of the Sun.

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Astronomical spectroscopy is the study of astronomy using the techniques of spectroscopy to measure the spectrum of electromagnetic radiation, including visible light, ultraviolet, X-ray, infrared and radio waves that radiate from stars and other celestial objects. A stellar spectrum can reveal many properties of stars, such as their chemical composition, temperature, density, mass, distance and luminosity. Spectroscopy can show the velocity of motion towards or away from the observer by measuring the Doppler shift. Spectroscopy is also used to study the physical properties of many other types of celestial objects such as planets, nebulae, galaxies, and active galactic nuclei.

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Jesse Leonard Greenstein was an American astronomer. His parents were Maurice G. and Leah Feingold.

<span class="mw-page-title-main">Halton Arp</span> American astronomer

Halton Christian "Chip" Arp was an American astronomer. He is remembered for his 1966 book Atlas of Peculiar Galaxies, which catalogued unusual looking galaxies and presented their images.

3C 433 is a Seyfert galaxy located in the constellation Vulpecula. It has a redshift of z =0.1016, and is classified as a peculiar radio galaxy with high luminosity other than its complex shell-type. Apart from that, it has a young stellar population and a radio structure mainly made up of knot and jet structures. Using mid-infrared wavelengths from Spitzer Observations, 3C 433 hosts a hidden quasar.

3C 286, also known by its position as 1328+307 or 1331+305, is a quasar at redshift 0.8493 with a radial velocity of 164,137 km/s. It is part of the Third Cambridge Catalogue of Radio Sources.

<span class="mw-page-title-main">3C 147</span> Quasar in the constellation Auriga

3C 147 (B0538+498) is a compact steep-spectrum (CSS) quasar that was discovered in 1964. It is located in the constellation Auriga not far in the sky from the 5th magnitude star Omicron Aurigae.

TON 618 is a hyperluminous, broad-absorption-line, radio-loud quasar, and Lyman-alpha blob located near the border of the constellations Canes Venatici and Coma Berenices, with the projected comoving distance of approximately 18.2 billion light-years from Earth. It possesses one of the most massive black holes ever found, at 40.7 billion M_☉.

Cyril Hazard is a British astronomer. He is known for revolutionising quasar observation with John Bolton in 1962. His work allowed other astronomers to find redshifts from the emission lines from other radio sources.

3C 138 is a quasar located in the constellation of Taurus. It has a redshift of (z) 0.76. The radio spectrum of this source appears both compact and steep, making it a compact steep-spectrum radio quasar. It is also one of the few 3C objects showing a defined and turn-over in its electromagnetic spectrum at low frequencies.

3C 356 is a distant radio galaxy located in the constellation of Draco, hosted by a merging pair of elliptical galaxies located at redshift (z) 1.079 with two radio cores having a separation gap of 5 arcseconds. It was first discovered as an astronomical radio source by P. Veron from a 3C revised catalogue in 1966 and such, shows an alignment effect at both wavelengths. The X-ray source luminosity for this galaxy is estimated to be 2.5 x 10⁴⁴ erg s^-1.

References

1 2 3 4 5 6 "NASA/IPAC Extragalactic Database". Results for 3C 48. Retrieved 2006-10-26.
↑ "3C 48". SIMBAD . Centre de données astronomiques de Strasbourg.
↑ Weaver, Kenneth F. (May 1974). "The Incredible Universe". National Geographic . 145 (5): 589–633.
↑ Matthews, Thomas A.; Sandage, Allan R. (1963). "Optical Identification of 3c 48, 3c 196, and 3c 286 with Stellar Objects". The Astrophysical Journal . 138: 30–56. Bibcode:1963ApJ...138...30M. doi: 10.1086/147615 .
↑ Greenstein, J. L.; Matthews, Thomas A. (1963). "Red-Shift of the Unusual Radio Source 3C48". Nature . 197 (4872): 1041–1042. Bibcode:1963Natur.197.1041G. doi:10.1038/1971041a0. S2CID 4193798.
↑ Todd A. Boroson & Oke, J. B. (1982). "Detection of the underlying galaxy in the QSO 3C48". Nature . 296 (5856): 397–399. Bibcode:1982Natur.296..397B. doi:10.1038/296397a0. S2CID 4284238.
↑ Witz, Stephan W. (4 December 2015). "Calibration and Flux Density Scale". National Radio Astronomy Observatory . Retrieved 15 May 2016.
↑ "Optical Identification of 3c 48, 3c 196, and 3c 286 with Stellar Objects" (journal). The Astrophysical Journal. IOP Publishing. 1963. pp. 30–56. doi:10.1086/147615. Archived from the original on 2019-07-12.

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[ned-1] 1 2 3 4 5 6 "NASA/IPAC Extragalactic Database". Results for 3C 48. Retrieved 2006-10-26.

[SIMBAD-2] "3C 48". SIMBAD . Centre de données astronomiques de Strasbourg.

[3] Weaver, Kenneth F. (May 1974). "The Incredible Universe". National Geographic . 145 (5): 589–633.

[4] Matthews, Thomas A.; Sandage, Allan R. (1963). "Optical Identification of 3c 48, 3c 196, and 3c 286 with Stellar Objects". The Astrophysical Journal . 138: 30–56. Bibcode:1963ApJ...138...30M. doi: 10.1086/147615 .

[5] Greenstein, J. L.; Matthews, Thomas A. (1963). "Red-Shift of the Unusual Radio Source 3C48". Nature . 197 (4872): 1041–1042. Bibcode:1963Natur.197.1041G. doi:10.1038/1971041a0. S2CID 4193798.

[6] Todd A. Boroson & Oke, J. B. (1982). "Detection of the underlying galaxy in the QSO 3C48". Nature . 296 (5856): 397–399. Bibcode:1982Natur.296..397B. doi:10.1038/296397a0. S2CID 4284238.

[NRAO-7] Witz, Stephan W. (4 December 2015). "Calibration and Flux Density Scale". National Radio Astronomy Observatory . Retrieved 15 May 2016.

[8] "Optical Identification of 3c 48, 3c 196, and 3c 286 with Stellar Objects" (journal). The Astrophysical Journal. IOP Publishing. 1963. pp. 30–56. doi:10.1086/147615. Archived from the original on 2019-07-12.

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3C 48

Contents

Nomenclature

History

Related Research Articles

References