Kepler's Supernova
Event type | Supernova |
---|---|
Ia[1][2] | |
Date | 8–9 October 1604 |
Right ascension | 17h 30m 42s |
Declination | −21° 29′ |
Epoch | J2000 |
Galactic coordinates | G4.5+6.8 |
Distance | Less than 20,000 light-years (6.1 kpc) |
Remnant | Shell |
Host | Milky Way |
Progenitor | White dwarf–red giant double star system |
Progenitor type | Type Ia supernova |
Colour (B-V) | Unknown |
Notable features | Latest observed supernova in the Milky Way. Maintained naked-eye visibility for 18 months. |
Peak apparent magnitude | −2.25 to −2.5 |
Other designations | 1ES 1727-21.4, 3C 358, ESO 588-4, GCRV 67121, HR 6515, IRAS 17276-2126, MRC 1727-214, PK 004+06 1, PN G004.5+06.8, 1RXS J173040.4-212836, SN 1604A, IRAS Z17276-2126, SN 1604, AJG 71, CSI-21-17276, CTB 41, Kes 57, MSH 17-2-11, OHIO T -246, PKS 1727-21, PKS 1727-214, PKS J1730-2129, [PBD2003] G004.5+06.8 |
Preceded by | SN 1572 |
Followed by | Cassiopeia A (unobserved, c. 1680), G1.9+0.3 (unobserved, c. 1868), SN 1885A (next observed) |
Related media on Commons | |
SN 1604, also known as Kepler's Supernova, Kepler's Nova or Kepler's Star, was a Type Ia supernova[1][2] that occurred in the Milky Way, in the constellation Ophiuchus. Appearing in 1604, it is the most recent supernova in the Milky Way galaxy to have been unquestionably observed by the naked eye,[3] occurring no farther than 6 kiloparsecs (20,000 light-years) from Earth. Before the adoption of the current naming system for supernovae, it was named for Johannes Kepler, the German astronomer who described it in De Stella Nova.
Observation
[edit]Visible to the naked eye, Kepler's Star was brighter at its peak than any other star in the night sky, with an apparent magnitude of −2.5. It was visible during the day for over three weeks. Records of its sighting exist in European, Chinese, Korean, and Arabic sources.[4][5]
It was the second supernova to be observed in a generation (after SN 1572 seen by Tycho Brahe in Cassiopeia). No further supernovae have since been observed with certainty in the Milky Way, though many others outside the galaxy have been seen since S Andromedae in 1885. SN 1987A in the Large Magellanic Cloud was visible to the naked eye at night.[6]
Evidence exists for two Milky Way supernovae whose electromagnetic radiation would have reached Earth c. 1680 and 1870 – Cassiopeia A, and G1.9+0.3 respectively. There is no historical record of either having been detected in those years, likely because absorption by interstellar dust obscured their visible light.[7]
The remnant of Kepler's supernova is considered to be one of the prototypical objects of its kind and is still an object of much study in astronomy.[8]
Controversies
[edit]Astronomers of the time (including Kepler) were concerned with observing the conjunction of Mars and Jupiter, which they saw as an auspicious conjunction linked to the Star of Bethlehem. However, cloudy weather prevented Kepler from making observations. Wilhelm Fabry, Michael Maestlin, and Helisaeus Roeslin were able to make observations on 9 October, but did not record the supernova.[9] The first recorded observation in Europe was by Lodovico delle Colombe in northern Italy on 9 October 1604.[10] Kepler was only able to begin his observations on 17 October while working at the imperial court in Prague for Emperor Rudolf II.[11] The supernova was subsequently named after him, even though he was not its first observer, as his observations tracked the object for an entire year. These observations were described in his book De Stella nova in pede Serpentarii ("On the new star in Ophiuchus's foot", Prague 1606).
Delle Colombe–Galileo controversy
[edit]In 1606, Delle Colombe published Discourse of Lodovico delle Colombe in which he shows that the "Star Newly Appeared in October 1604 is neither a Comet nor a New Star" and where he defended an Aristotelian view of cosmology after Galileo Galilei had used the occasion of the supernova to challenge the Aristotelian system.[12] The description of Galileo's claims is as follows:
Galileo explained the meaning and relevance of parallax, reported that the nova displayed none, and concluded, as a certainty, that it lay beyond the moon. Here he might have stopped, having dispatched his single arrow. Instead he sketched a theory that ruined the Aristotelian cosmos: the nova very probably consisted of a large quantity of airy material that issued from the earth and shone by reflected sunlight, like Aristotelian comets. Unlike them, however, it could rise beyond the moon. It not only brought change to the heavens, but did so provocatively by importing corruptible earthy elements into the pure quintessence. That raised heaven-shattering possibilities. The interstellar space might be filled with something similar to our atmosphere, as in the physics of the Stoics, to which Tycho had referred in his lengthy account of the nova of 1572. And if the material of the firmament resembled that of bodies here below, a theory of motion built on experience with objects within our reach might apply also to the celestial regions. "But I am not so bold as to think that things cannot take place differently from the way I have specified."[13]
Kepler–Roeslin controversy
[edit]In Kepler's De Stella Nova (1606), he criticized Roeslin concerning this supernova. Kepler argued that in his astrological prognostications, Roeslin had picked out just the two comets, the Great Comet of 1556 and 1580. Roeslin responded in 1609 that this was indeed what he had done. When Kepler replied later that year, he simply observed that by including a broader range of data Roeslin could have made a better argument.[14]
Supernova remnant
[edit]The supernova remnant of SN 1604, Kepler's Star, was discovered in 1941 at the Mount Wilson Observatory as a dim nebula with a brightness of 19 mag.[15] Only filaments can be seen in visible light, but it is a strong radio and X-ray source. Its diameter is 4 arc min. Distance estimates place it between 3 and more than 7 kiloparsecs (10,000 to 23,000 lightyears),[16] with the current consensus being a distance of 5±1 kpc, as of 2021.[17]
The available evidence supports a type Ia supernova as the source of this remnant,[1] which is the result of a carbon-oxygen white dwarf interacting with a companion star.[18] The integrated X-ray spectrum resembles that of Tycho's supernova remnant, a type Ia supernova. The abundance of oxygen relative to iron in the remnant of SN 1604 is roughly solar, whereas a core-collapse scenario should produce a much higher abundance of oxygen. No surviving central source has been identified, which is consistent with a type Ia event. Finally, the historical records for the brightness of this event are consistent with type Ia supernovae.[1]
There is evidence for interaction of the supernova ejecta with circumstellar matter from the progenitor star, which is unexpected for type Ia but has been observed in some cases.[1] A bow shock located to the north of this system is believed to have been created by mass loss prior to the explosion.[16] Observations of the remnant are consistent with the interaction of a supernova with a bipolar planetary nebula that belonged to one or both of the progenitor stars.[18] The remnant is not spherically symmetric, which is likely due to the progenitor being a runaway star system. The bow shock is caused by the interaction of the advancing stellar wind with the interstellar medium. A remnant rich in nitrogen and silicon indicates that the system consisted of a white dwarf with an evolved companion that had likely already passed through the asymptotic giant branch stage.[17]
See also
[edit]References
[edit]- ^ a b c d e "Chandra X-Ray Observatory". Kepler's Supernova Remnant: A Star's Death Comes to Life. Retrieved 16 January 2006.
- ^ a b Reynolds, S. P.; Borkowski, K. J.; Hwang, U.; Hughes, J. P.; Badenes, C.; Laming, J. M.; Blondin, J. M. (2 October 2007). "A Deep Chandra Observation of Kepler's Supernova Remnant: A Type Ia Event with Circumstellar Interaction". The Astrophysical Journal. 668 (2): L135–L138. arXiv:0708.3858. Bibcode:2007ApJ...668L.135R. doi:10.1086/522830.
- ^ "APOD: 2013 May 15 – Kepler's Supernova Remnant in X-Rays". NASA.gov. Archived from the original on 10 April 2019. Retrieved 23 February 2024.
- ^ Stephenson, F. Richard & Green, David A., Historical Supernovae and their Remnants, Oxford, Clarendon Press, 2002, pp. 60–71.
- ^ Neuhäuser, Ralph; Rada, Wafiq; Kunitzsch, Paul; Neuhäuser, Dagmar L. (2016). "Arabic Reports about Supernovae 1604 and 1572 in Rawḥ al-Rūḥ by cĪsā b. Luṭf Allāh from Yemen". Journal for the History of Astronomy. 47 (4): 359–374. Bibcode:2016JHA....47..359N. doi:10.1177/0021828616669894. S2CID 125393243.
- ^ "SN1987A in the Large Magellanic Cloud". ESO.org. European Southern Observatory. 27 February 2019. Retrieved 25 November 2019.
- ^ "Chandra X-Ray Observatory". Discovery of Most Recent Supernova in Our Galaxy, May 14, 2008. Retrieved 2 May 2012.
- ^ "Chandra :: Photo Album :: Kepler's Supernova Remnant :: September 11, 2012". chandra.harvard.edu. Retrieved 12 April 2020.
- ^ Burke-Gaffney, W. (1937). "Kelper and the Star of Bethlehem" (PDF). Journal of the Royal Astronomical Society of Canada. 31: 417–425. Bibcode:1937JRASC..31..417B. Retrieved 21 January 2018.
- ^ Delle Colombe L., Discorso di Lodovico Delle Colombe nel quale si dimostra che la nuova Stella apparita l'Ottobre passato 1604 nel Sagittario non è Cometa, ne stella generata, ò creata di nuovo, ne apparente: ma una di quelle che furono da principio nel cielo; e ciò esser conforme alla vera Filosofia, Teologia, e Astronomiche dimostrazioni, Firenze, Giunti, 1606.
- ^ "Bill Blair's Kepler's Supernova Remnant Page". Archived from the original on 16 March 2016. Retrieved 7 October 2009.
- ^ delle Colombe, Lodovico (1606). Discorso di Lodovico delle Colombe (in Italian).
- ^ Heilbron, John L. (2010). Galileo. Oxford University Press, p. 120.
- ^ Fritz, Gerd. "Dialogical Structures in 17th Century Controversies" (PDF). www.festschrift-gerd-fritz.de. Gerd fritz. Archived (PDF) from the original on 9 October 2022. Retrieved 21 January 2018.
- ^ Baade, W. (1943). "Nova Ophiuchi of 1604 AS a Supernova". The Astrophysical Journal. 97: 119. Bibcode:1943ApJ....97..119B. doi:10.1086/144505.
- ^ a b Patnaude, Daniel J.; Badenes, Carles; Park, Sangwook; Laming, J. Martin (2012). "The Origin of Kepler's Supernova Remnant". The Astrophysical Journal. 756 (1): 6. arXiv:1206.6799. Bibcode:2012ApJ...756....6P. doi:10.1088/0004-637X/756/1/6. S2CID 119104810.
- ^ a b Kasuga, Tomoaki; Vink, Jacco; Katsuda, Satoru; Uchida, Hiroyuki; Bamba, Aya; Sato, Toshiki; Hughes, John P. (July 2021). "Spatially Resolved RGS Analysis of Kepler's Supernova Remnant". The Astrophysical Journal. 915 (1): 42. arXiv:2105.04235. Bibcode:2021ApJ...915...42K. doi:10.3847/1538-4357/abff4f. S2CID 234336681. 42.
- ^ a b Chiotellis, A.; Boumis, P.; Spetsieri, Z. T. (May 2020). "The Interaction of Type Ia Supernovae with Planetary Nebulae: The Case of Kepler's Supernova Remnant". Galaxies. 8 (2): 38. arXiv:2004.14493. Bibcode:2020Galax...8...38C. doi:10.3390/galaxies8020038.
Further reading
[edit]- Blair, William P.; Long, Knox S.; Vancura, Olaf (1991). "A detailed optical study of Kepler's supernova remnant". Astrophysical Journal. 366: 484–494. Bibcode:1991ApJ...366..484B. doi:10.1086/169583.
External links
[edit]- Light curves Archived 27 June 2020 at the Wayback Machine on the Open Supernova Catalog Archived 3 March 2016 at the Wayback Machine
- "SN1604". spider@SEDS. Archived from the original on 17 October 2013. Retrieved 16 October 2014.
- Simulation of the movement of the planets around Kepler's supernova in 1604 and 1605