SN 2002cx

Last updated
SN 2002cx
Event type Supernova   OOjs UI icon edit-ltr-progressive.svg
Peculiar Ia [1]
Date2002 May 12.21 UT
Constellation Virgo   OOjs UI icon edit-ltr-progressive.svg
Right ascension 13h 13m 49.72s [2]
Declination +6° 57 31.9 [1] [2]
Epoch J2000
Distance Z of 0.024 [3]
Redshift 0.0236, 0.0244, 0.0241, 0.0242, 0.0243, 0.0249  OOjs UI icon edit-ltr-progressive.svg
Host CGCG 044-035 [1]
Colour (B-V)0.04±0.05 [4]
Peak apparent magnitude +17.57±0.15 [5]
Other designationsSN 2002cx
  Commons-logo.svg Related media on Commons

SN 2002cx is a peculiar type Ia supernova. [6] [7] [8] It was discovered in May 2002 by a team of researchers from LBL. [2] It behaved differently from normal type Ia supernovae, and differently from several other previously observed peculiar type Ia supernovae including SN 1991T and SN 1991bg. [4] [9]

Contents

SN 2002cx is now classified as type Iax supernova, which are subluminal and do not result in complete destruction of the progenitor white dwarf. [10]

Discovery

SN 2002cx was discovered on 2002 May 12.21 UT by W. M. Wood-Vasey, G. Aldering, and P. Nugent of LBL with the Oschin 1.2-m telescope at Palomar. [1] [2] On 2002 May 17.2 a spectrum taken by T. Matheson, S. Jha, P. Challis, and R. Kirshner of the CfA with the 1.5-m telescope at FLWO suggested it was a peculiar SN 1991T like type Ia. [1] [11] SN 2002cx had photometric follow up taken at Lick using KAIT and the Nickel telescope, and further spectra were taken at FLWO and Keck. [1]

Features

Light curve

The light curve of SN 2002cx SN 2002cx Lightcurve.svg
The light curve of SN 2002cx

SN 2002cx hit maximum light in the B-band at 2452415.2 JD (2002 May 20.7) at 17.68, and in the V-band on 2452417.5 JD (2002 May 23) at 17.57. [12] The B-band light curve of SN 2002cx before 15 days after maximum evolves in a similar manner to SN 1999ac, brightening faster than SN 1991T but slower than SN 1994D or SN 2000cx. [9] SN 2002cx declines in brightness faster than SN 1991T and SN 2000cx in the B-band. [9] In the V-band SN 2002cx is similar to SN 1999ac until 30 days after max. [9] Again SN 2002cx declines faster in the V-band than SN 1991T, but slower than is typical for a type Ia. [9]

SN 2002cx is peculiar in the R-band, as it brightens very fast in a manner wholly different from SN 1999ac. [13] It has no secondary maximum in R-band as expected if it were similar to SN 1991T, but instead has a plateau after max. [13] The R-band also declines more slowly than normal. [13] The I-band behaves similarly to the R-band, with a quick brightening, a plateau and slow decline. [13] While a plateau in the I-band is expected for sub-luminous supernovae, the following slow decline is not. [13]

Spectra

Four spectra of SN 2002cx SN 2002cx Spectra.svg
Four spectra of SN 2002cx

The first spectrum of SN 2002cx was obtained with FLWO on 2002 May 17, 4 days before B-band max. [14] At this point SN 2002cx is similar to SN 1997br as both have a blue continuum, with absorption lines from Fe III λ4404 and Fe III λ5129. [14] Si II λ6355 though is not apparent in SN 2002cx at this point, and it has very weak Ca II H & K lines suggesting that SN 2002cx is similar to SN 1991T which also lacked such lines. [14] This spectrum for SN 2002cx has a low expansion velocity measuring only ~6400 km s−1. [14] This marked one way in which it was different from SN 1997br, as SN 1997br's expansion velocity was ~10,400 km s−1 at the same point relative to its own B-band maximum. [14] At the time of measurement SN 2002cx's expansion velocity was the lowest measured for an early time type Ia, [14] Another spectrum taken on 2002 May 20, 1 day before B-band maximum light, showed little evolution from the one taken on 2002 May 17. [15]

Four later spectra were taken on June 2, June 6, June 12, and June 16 at FLWO. [16] The spectrum of SN 2002cx has evolved by this point to have a redder continuum. [16] It has also lost the Fe III absorption lines and its Fe II lines have gained prominence at λ4555 and λ5129. [16] The Ca II H & K lines continue to remain weak, a further departure from SN 1997br. [16] Unlike another type of sub-luminous type Ia, SN 1991bg, SN 2002cx does not show Ti II lines around 4100–4400 Å. [16]

Spectra were taken at Keck corresponding to 20, 25, and 26 days after maximum light in the B-band. [17] So little evolution was observed between these spectra that they were all combined in order to increase the signal-to-noise ratio and study less pronounced features. [17] Fe II still dominates the spectrum. [17] The Ca II infrared triplet is weak in SN 2002cx as compared to other type Ia supernovae, as expected since the Ca II H & K line is also weak in SN 2002cx. [17] Unlike other type Ia supernova, SN 2002cx has double-peaked emission lines which may be due to jet-like emissions or rotating ejecta, or may simply only be seen in SN 2002cx because its low expansion velocity does not wash them out. [17] The emission or ejecta hypothesis is considered less likely because if it were the case all the peaks should share equal separation, which they do not. [17] [18] SN 2002cx has absorption and emission lines between 6400 Å and 7000 Å that are unique among previously discovered type Ia supernovae. [18]

A final spectrum of SN 2002cx was taken on July 16, 56 days after B-band maximum. [19] SN 2002cx was by then in the nebular phase, with emission lines dominating over absorption lines. [19] The lines were far narrower than previously observed type Ia supernovae and are less pronounced as well. [19] SN 2002cx most clearly differs from other type Ia supernovae in the region between 6500 Å and 8500 Å where it has a primarily flat continuum and weak Ca II infrared triplet absorption. [19] Because this is the region covered by the R and I-bands, it may explain the odd color evolution of SN 2002cx in these bands. [19]

SN 2002cx did not evolve much between 4 days and 1 day before max, nor did it evolve much from 12 days after max to 27 days after max, [16] However, it underwent dramatic evolution during the two weeks after maximum light in the B-band. [16]

Based on the odd behavior of SN 2002cx's spectrum there are some questions as to whether it is a type Ia supernova or not. [20] Although it does not show Si II lines neat 6150 Å as is required of a type Ia, SN 2002cx's evolution is explainable using the paradigm of other type Ia observations and so Li et al. consider their classification as a type Ia as secure. [20]

Color

SN 2002cx does not suffer from much host related reddening, as evidenced by its very blue spectra. [4] It is extinct in B−V color by 0.034 magnitudes from dust in Milky Way. [4]

SN 2002cx is similar to SN 1999ac in B−V at max, but also at times as late as 50 days after max which is unexpected as the two supernovae evolve differently at late times. [4] SN 2002cx has a B−V color of −0.04±0.04 at 4 days before max, and 0.04±0.05 at the time of max in the B-band which is bluer than SN 1991bg at the same time. [4] The color of SN 2002cx is consistent with Lira-Phillips law at late times. [21]

The V−R color of SN 2002cx evolves similar to other type Ia supernovae before 5 days after max, although it is somewhat redder. [21] After 5 days after max SN 2002cx gets progressively redder, although still slightly bluer than SN 1991bg. [4] At 25 days after max SN 2002cx continues to redden, while SN 1991bg starts to get bluer. [4]

SN 2002cx's V−I color is red for all times, only slightly bluer than SN 1991bg before 25 days after max, and redder after 25 days after max. [4]

Related Research Articles

<span class="mw-page-title-main">Supernova</span> Astrophysical phenomenon

A supernova is a powerful and luminous explosion of a star. A supernova occurs during the last evolutionary stages of a massive star, or when a white dwarf is triggered into runaway nuclear fusion. The original object, called the progenitor, either collapses to a neutron star or black hole, or is completely destroyed to form a diffuse nebula. The peak optical luminosity of a supernova can be comparable to that of an entire galaxy before fading over several weeks or months.

<span class="mw-page-title-main">Type Ia supernova</span> Type of supernova in binary systems

A Type Ia supernova is a type of supernova that occurs in binary systems in which one of the stars is a white dwarf. The other star can be anything from a giant star to an even smaller white dwarf.

<span class="mw-page-title-main">SN 1994D</span> Type Ia supernova

SN 1994D was a Type Ia supernova event in the outskirts of galaxy NGC 4526. It was offset by 9.0″ west and 7.8″ south of the galaxy center and positioned near a prominent dust lane. It was caused by the explosion of a white dwarf star composed of carbon and oxygen. This event was discovered on March 7, 1994 by R. R. Treffers and associates using the automated 30-inch telescope at Leuschner Observatory. It reached peak visual brightness two weeks later on March 22. Modelling of the light curve indicates the explosion would have been visible around March 3-4. A possible detection of helium in the spectrum was made by W. P. S. Meikle and associates in 1996. A mass of 0.014 to 0.03 M in helium would be needed to produce this feature.

<span class="mw-page-title-main">NGC 2207 and IC 2163</span> Pair of colliding spiral galaxies in the constellation Canis Major

NGC 2207 and IC 2163 are a pair of colliding spiral galaxies about 80 million light-years away in the constellation Canis Major. Both galaxies were discovered by John Herschel in 1835.

<span class="mw-page-title-main">NGC 1309</span> Spiral galaxy in the constellation Eridanus

NGC 1309 is a spiral galaxy located approximately 120 million light-years away, appearing in the constellation Eridanus. It is about 75,000 light-years across, and is about 3/4s the width of the Milky Way. Its shape is classified as SA(s)bc, meaning that it has moderately wound spiral arms and no ring. Bright blue areas of star formation can be seen in the spiral arms, while the yellowish central nucleus contains older-population stars. NGC 1309 is one of over 200 members of the Eridanus Group of galaxies.

<span class="mw-page-title-main">History of supernova observation</span> Ancient and modern recorded observations of supernovae explosions

The known history of supernova observation goes back to 1006 AD. All earlier proposals for supernova observations are speculations with many alternatives.

<span class="mw-page-title-main">Type Ib and Ic supernovae</span> Types of supernovae caused by a star collapsing

Type Ib and Type Ic supernovae are categories of supernovae that are caused by the stellar core collapse of massive stars. These stars have shed or been stripped of their outer envelope of hydrogen, and, when compared to the spectrum of Type Ia supernovae, they lack the absorption line of silicon. Compared to Type Ib, Type Ic supernovae are hypothesized to have lost more of their initial envelope, including most of their helium. The two types are usually referred to as stripped core-collapse supernovae.

<span class="mw-page-title-main">Type II supernova</span> Explosion of a star 8 to 45 times the mass of the Sun

A Type II supernova or SNII results from the rapid collapse and violent explosion of a massive star. A star must have at least eight times, but no more than 40 to 50 times, the mass of the Sun (M) to undergo this type of explosion. Type II supernovae are distinguished from other types of supernovae by the presence of hydrogen in their spectra. They are usually observed in the spiral arms of galaxies and in H II regions, but not in elliptical galaxies; those are generally composed of older, low-mass stars, with few of the young, very massive stars necessary to cause a supernova.

<span class="mw-page-title-main">Pair-instability supernova</span> Type of high-energy supernova in very large stars

A pair-instability supernova is a type of supernova predicted to occur when pair production, the production of free electrons and positrons in the collision between atomic nuclei and energetic gamma rays, temporarily reduces the internal radiation pressure supporting a supermassive star's core against gravitational collapse. This pressure drop leads to a partial collapse, which in turn causes greatly accelerated burning in a runaway thermonuclear explosion, resulting in the star being blown completely apart without leaving a stellar remnant behind.

SN 2003H was a supernova that appeared halfway between the colliding NGC 2207 and IC 2163 galaxies. It was discovered on January 8, 2003, by the Lick Observatory and Tenagra Supernova Searches (LOTOSS).

<span class="mw-page-title-main">SCP 06F6</span> Astronomical object discovered in 2006

SCP 06F6 is an astronomical object of unknown type, discovered on 21 February 2006 in the constellation Boötes during a survey of galaxy cluster CL 1432.5+3332.8 with the Hubble Space Telescope's Advanced Camera for Surveys Wide Field Channel.

SN 2005gj was a supernova located approximately 864 million light years away from Earth. It was discovered on September 27, 2005, by the Sloan Digital Sky Survey and the Nearby Supernova Factory. 2005gj was noted because it had qualities of both type Ia and type IIn supernovae, and because hydrogen emission lines were found in its spectrum. These hydrogen lines, which were found on the spectrum at redshift z=0.0613, are thought to be indicative of interactions with a circumstellar medium by the supernova's ejected matter or white dwarf progenitor. Such emission lines are extremely rare in Type Ia supernovae – only one other Type Ia, SN 2002ic, has been observed to exhibit the same properties. However, 2005gj's CSM interaction was much stronger and more clearly observed than 2002ic's. The mass-loss history 2005gj's hydrogen lines suggest has been cited as evidence that luminous blue variable (LBV) hypergiants can be progenitors of thermonuclear supernovae.

<span class="mw-page-title-main">SN 2008ha</span> Supernova in the constellation Pegasus

SN 2008ha was a type Ia supernova which was first observed around November 7, 2008 in the galaxy UGC 12682, which lies in the constellation Pegasus at a distance of about 21.3 megaparsecs (69 Mly) from Earth.

<span class="mw-page-title-main">Phillips relationship</span> Relationship in astrophysics

In astrophysics, the Phillips relationship is the relationship between the peak luminosity of a Type Ia supernova and the speed of luminosity evolution after maximum light. The relationship was independently discovered by the American statistician and astronomer Bert Woodard Rust and the Soviet astronomer Yury Pavlovich Pskovskii in the 1970s. They found that the faster the supernova faded from maximum light, the fainter its peak magnitude was. As a main parameter characterizing the light curve shape, Pskovskii used β, the mean rate of decline in photographic brightness from maximum light to the point at which the luminosity decline rate changes. β is measured in magnitudes per 100-day intervals. Selection of this parameter is justified by the fact that, at that time, the probability of discovering a supernova before the maximum light, and obtain the full light curve, was small. Moreover, the existing light curves were mostly incomplete. On the other hand, to determine the decline after the maximum light was rather simple for most observed supernovae.

<span class="mw-page-title-main">SN 1994I</span> Supernova event from 1994 in constellation Canes Venatici

SN 1994I is a Type Ic supernova discovered on April 2, 1994 in the Whirlpool Galaxy by amateur astronomers Tim Puckett and Jerry Armstrong of the Atlanta Astronomy Club. Type Ic supernova are a rare type of supernova that result from the explosion of a very massive star that has shed its outer layers of hydrogen and helium. The explosion results in a highly luminous burst of radiation that then dims over the course of weeks or months. SN 1994I was a relatively nearby supernova, and provided an important addition to the then small collection of known Type Ic supernova. Very early images were captured of SN 1994I, as two high school students in Oil City, Pennsylvania serendipitously took images of the Whirlpool Galaxy using the 30-inch telescope at Leuschner Observatory on March 31, 1994, which included SN 1994I just after it began to brighten.

<span class="mw-page-title-main">SN 1998aq</span> Supernova in the constellation Ursa Major

SN 1998aq is a nearby supernova located in the intermediate spiral galaxy NGC 3982, offset 18″ west and 7″ of the galactic nucleus. It was discovered April 13, 1998 by amateur astronomer Mark Armstrong and was confirmed by fellow British amateur Ron Arbour; both members of the U.K. Supernova/Nova Patrol. The event was not visible on a prior check by Armstrong made April 7. It reached peak brightness on April 27, and 15 days later had declined by 1.14 magnitudes in the B (blue) band.

SN 1972E was a supernova in the galaxy NGC 5253 that was discovered 13 May 1972 with an apparent B magnitude of about 8.5, shortly after it had reached its maximum brightness. In terms of apparent brightness, it was the second-brightest supernova of any kind of the 20th century. It was observed for nearly 700 days, and it became the prototype object for the development of theoretical understanding of Type Ia supernovae.

<span class="mw-page-title-main">SN 2014J</span> Supernova in Messier 82

SN 2014J was a type-Ia supernova in Messier 82 discovered in mid-January 2014. It was the closest type-Ia supernova discovered for 42 years, and no subsequent supernova has been closer as of 2023. The supernova was discovered by chance during an undergraduate teaching session at the University of London Observatory. It peaked on 31 January 2014, reaching an apparent magnitude of 10.5. SN 2014J was the subject of an intense observing campaign by professional astronomers and was bright enough to be seen by amateur astronomers.

<span class="mw-page-title-main">ASASSN-15lh</span> 2015 hypernova event in the constellation Indus

ASASSN-15lh is an extremely luminous astronomical transient event discovered by the All Sky Automated Survey for SuperNovae (ASAS-SN), with the appearance of a superluminous supernova event. It was first detected on June 14, 2015, located within a faint galaxy in the southern constellation Indus, and was the most luminous supernova-like object ever observed. At its peak, ASASSN-15lh was 570 billion times brighter than the Sun, and 20 times brighter than the combined light emitted by the Milky Way Galaxy. The emitted energy was exceeded by PS1-10adi.

iPTF14hls Supernova star

iPTF14hls is an unusual supernova star that erupted continuously for about 1,000 days beginning in September 2014 before becoming a remnant nebula. It had previously erupted in 1954. None of the theories nor proposed hypotheses fully explain all the aspects of the object.

References

  1. 1 2 3 4 5 6 Li et al., 2003 p. 5
  2. 1 2 3 4 Wood-Vasey et al., 2002
  3. Li et al., 2003 p. 14
  4. 1 2 3 4 5 6 7 8 9 Li et al., 2003 p. 12
  5. Li et al., 2003 p. 58
  6. Li et al., 2003 p. 1
  7. Branch et al., 2004
  8. Jha et al., 2006
  9. 1 2 3 4 5 Li et al., 2003 p. 10
  10. Jha, Saurabh W. (2017). Type Iax Supernovae. pp. 375–401. arXiv: 1707.01110 . Bibcode:2017hsn..book..375J. doi:10.1007/978-3-319-21846-5_42. ISBN   978-3-319-21845-8.{{cite book}}: |journal= ignored (help)
  11. Matheson et al., 2002
  12. Li et al., 2003 p. 9
  13. 1 2 3 4 5 Li et al., 2003 p. 11
  14. 1 2 3 4 5 6 Li et al., 2003 p. 15
  15. Li et al., 2003 p. 16
  16. 1 2 3 4 5 6 7 Li et al., 2003 p. 17
  17. 1 2 3 4 5 6 Li et al., 2003 p. 18
  18. 1 2 Li et al., 2003 p. 19
  19. 1 2 3 4 5 Li et al., 2003 p. 20
  20. 1 2 Li et al., 2003 p. 24
  21. 1 2 Li et al., 2003 p. 13

Bibliography