阿佩普位於星座矩尺座,在赤經16h 00m 50.5s和赤緯-51° 42′ 45″[1]。該系統可以解析為兩個組成部分:「中央發動機」沃夫-瑞葉聯星,和「北方伴星」超巨星[20]。系統的總視星等為17.5,分辨出的中央發動機和北方伴星的視星等分別為19.0和17.8[21]。它的紅外光譜能量分佈(SED)是獨一無二的,亮度範圍從2.2μm處的6.4等到22μm處的-2.4等[22]。使用歐洲南方天文台(ESO)的儀器SINFONI,在甚大望遠鏡上進行的調查量測到,中央發動機在紅外J波段(英语:J band (infrared))中的視星等為7001102000000000000♠10.2±0.2,北方伴星的視星級為7000960000000000000♠9.6±0.2[23]。SINFONI 還量測了系統在K波段中的表觀星等,對於中央發動機為7000690000000000000♠6.9±0.2,對C為7000810000000000000♠8.1±0.2[24], 在 L 波段(英语:L band (infrared)),對於中央發動機為7000470000000000000♠4.7±0.1,北方辦星為7000730000000000000♠7.3±0.1[24],和在M波段(英语:M band (infrared))的中央發動機為7000440000000000000♠4.4±0.3,北方伴星為7000700000000000000♠7.0±0.2[24]。SINFONI的觀測進一步詳細說明,北方伴星可能是一顆傳統的B1Ia+高光度恆星[25]。A和B顯示了WC7恆星的典型光譜[26],但具有額外的WN4或WN5恆星特徵,理論上來自中央發動機的恆星之一;如果得到證實,這將使阿佩普成為一個罕見的WR星的聯星系統[27]。另一種基於SINFONI數據的假設認為,光譜可能都來自一顆不尋常的過渡WN/WC星,而北方伴星則是一顆傳統的OB恆星[28]。將WR星大犬座EZ和WR 90的光譜結合起來,將產生與WR聯星觀測到的光譜幾乎相同的光譜。
^ 1.01.11.2Callingham et al. 2018,page 3, "Figure 1. VISIR 8.9 μm image of Apep taken on 2016 August 13, displaying the exotic dust pattern being sculpted by the system. The 2.24 μm NACO image of the region bounded by the blue box, of dimension 1.8" × 1.8", is shown in the upper right corner."
^ 5.05.1Callingham et al. 2018,page 3, "we here adopt the moniker "Apep" after the sinuous form of this infrared plume [...] The serpent diety from Egyptian mythology; mortal enemy of sun god Ra. We think this is an apt allusion to the image which evokes a star embattled within a dragon’s coils."
^ 6.06.16.2Dvorsky, George. Stunning Pinwheel Nebula Is a Cosmic Cataclysm in the Making. Gizmodo. 19 November 2018 [20 November 2018]. (原始内容存档于20 November 2018). ...but to the researchers who recently investigated this enigmatic object, it’s simply "Apep" [...] The speed of gas within the nebula was clocked at 12 million kilometers per hour [...] featuring a massive triple star system at its core—a binary pair and a lone star...
^ 7.07.17.2Letzter, Rafi. This Spinning, Snakelike Star System Might Blast Gamma Rays into the Milky Way When It Dies. Live Science. 19 November 2018 [20 November 2018]. (原始内容存档于20 November 2018). For the first time, astronomers have found a star system in our galaxy that could produce a gamma-ray burst [...] the researchers nicknamed it "Apep" after the Egyptian snake-deity of chaos. [...] The name works nicely for the system, which is surrounded by long, fiery pinwheels of matter cast out into space...
^ 9.09.19.29.3Carpineti, Alfredo. This 'Cosmic Serpent' Is The First System Of Its Kind To Be Discovered In Our Galaxy. IFL Science!. 19 November 2018 [20 November 2018]. (原始内容存档于20 November 2018). Three stars are in this picture, although the two Wolf-Rayet stars look like a single one in the center [...] the winds are moving at 12 million kilometers (7.5 million miles) per hour. [...] The observations were possible thanks to the Very Large Telescope [...] the dust at the edge of the system is moving at the slower pace of 2 million kilometers (1.2 million miles) per hour.
^Plait 2018,"At 250 billion kilometers out from the bright star (about ten times the distance of Neptune from the Sun), it would take more than 10,000 years to circle it once..."
^ 12.012.112.2Strom, Marcus. Doomed star in Milky Way threatens rare gamma-ray burst. University of Sydney. 20 November 2018 [20 November 2018]. (原始内容存档于20 November 2018). ...the astronomers have measured the velocity of the stellar winds as fast as 12 million kilometres an hour, about 1 percent the speed of light. [...] We discovered this star as an outlier in a survey with a radio telescope operated by the University of Sydney.
^Plait 2018,"Sometimes, if they are in a tight binary, you get a pinwheel. The most famous example of that is WR 104..."
^Plait 2018,"The astronomers who observed it think that the primary (brighter) one is spinning extremely rapidly, so fast it's nearly at the breakup rate — in other words, spinning so fast that the gravity of the star at the surface is nearly balanced by the centrifugal force outwards."
^ 15.015.1Weule, Genelle. Spectacular cosmic pinwheel is a 'ticking bomb' set to blast gamma rays across the Milky Way. ABC News Australia. 20 November 2018 [20 November 2018]. (原始内容存档于20 November 2018). Writing in the journal Nature Astronomy [...] the most violent star is creating stellar winds at two speeds — fast at the poles, slow at the equator [...] the beautiful pinwheel of blazing dust is created not by the fast polar winds, but by the turbulence that arises when the second star in the central engine passes through that first star's slow-moving equatorial wind.
^ 16.016.116.2Devitt, James. Scientists Discover New "Pinwheel" Star System. New York University. 19 November 2018 [20 November 2018]. (原始内容存档于20 November 2018). "It was not expected such a system would be found in our galaxy—only in younger galaxies much further away," [...] The discovery of the system [...] also included scientists from the Netherlands Institute for Radio Astronomy, the University of Sydney, the University of Edinburgh, the University of Sheffield, and the University of New South Wales. [...] is adorned with a dust "pinwheel"— whose strangely slow motion suggests current theories on star deaths may be incomplete.
^Clery, Daniel. Massive star system primed for intense explosion. Science. 20 November 2018 [20 November 2018]. (原始内容存档于20 November 2018). One of stars is an unusually massive sun known as a Wolf-Rayet star. When such stars run out of fuel, they collapse, causing a supernova explosion. Theorists believe that if the Wolf-Rayet star is also spinning fast, the explosion will produce intense jets of gamma rays out of either pole...
^ 18.018.1Callingham et al. 2018,page 18–19, "If we use the visual extinction AV = 11.4 [...] we need a distance of d = 7000240000000000000♠2.4+0.2 −0.5 to get realistic absolute magnitudes for the components. [...] Despite these uncertainties, all lines of evidence suggest that Apep is located [less-than around] 4.5 kpc, and likely around d ≈ 2.4 kpc."
^ 19.019.1Mannix, Liam. Super-powerful interstellar 'ticking time bomb' found not far from Earth. The Sydney Morning Herald. 20 November 2018 [20 November 2018]. (原始内容存档于20 November 2018). In a part of the Milky Way 8000-odd light-years away [...] The system was spotted by PhD student Dr Joe Callingham while he was sorting through data, and later confirmed using the Anglo-Australian Telescope at Coonabarabran in regional NSW.
^Callingham et al. 2018,page 2, "The 2.24μm NACO observation (Figure 1, inset) resolves Apep into a 0.739" ± 0.002" binary with a fainter companion to the North."
^Callingham et al. 2018,page 18, "...the known visual magnitude V = 17.5 for Apep (V = 17.8 for the OB supergiant that is the northern companion and V = 19.0 for the Central Engine)..."
^Callingham et al. 2018,page 18–19, "...was first noted as a high-luminosity outlier in our Galactic plane X-ray and radio survey, and revealed as an exceptional object on considering its infra-red spectral energy distribution (SED), where it brightens from an apparent magnitude of 6.4 at 2.2μm to −2.4 at 22μm, with both measurements on the Vega system."
^Callingham et al. 2018,page 14, "Apep was resolved by SINFONI [...] We summed the J-band data over the Central Engine and northern companion to derive the J-band magnitudes of 7001102000000000000♠10.2±0.2 and 7000960000000000000♠9.6±0.2, respectively."
^ 24.024.124.2Callingham et al. 2018,page 22, "Supplementary Information Table 2. Summary of the NACO observations of Apep. Separation refers to the angular separation between the Central Engine and northern companion, identified in the inset of Figure 1. The uncertainties reported are for 90% confidence."
^Callingham et al. 2018,page 21, "Despite this, we favour the northern companion being an B1 Ia+ supergiant but further observations, particularly optical spectra, are necessary to confirm this spectral type."
^Callingham et al. 2018,page 20, "...the spectrum of Apep shows stronger He II and weaker C IV line emission than is stereotypical for a WC7 star."
^Callingham et al. 2018,page 20, "The weakness in the J-band, where dust emission is negligible [...] points to the additional continuum from a companion star. The abnormal strength of the He II lines for a WC7 star suggests an early WN sub-type companion. The absence of N V and relative weakness of He I, and with comparison to WN spectra, implies the presence of a subtype WN4 or WN5 star. Double WR binaries are, however, rare, with very few known."
^Callingham et al. 2018,page 21, "An alternative spectral subtype classification to the WC7+WN4-5 model, that equally well describes the spectra shown in Figure 2, is that of a WR star in the brief transitory phase between WN and WC (WN/WC) with an unseen OB-type companion."
^Callingham et al. 2018,page 25, "Supplementary Information Table 3. Summary of the 0.2 and 10.0 keV observations of Apep. ObsID corresponds to the unique identification number assigned to each observation by the respective X-ray observatory.
^Callingham 2018,"The path that led to the discovery of Apep started with a relatively simple crossmatch between X-ray and radio surveys in the last year of my undergraduate study at the University of Sydney..."
^Callingham 2018,"Momentum was behind the idea that Apep was a new colliding-wind binary but the radio emission would make it the brightest radio colliding-wind binary discovered outside of the unique object Eta Carinae..."
^Callingham 2018,"This is where the imaging guru Peter Tuthill (University of Sydney) comes into the story as the extreme infrared properties of Apep particularly caught his attention. [...] It immediately brought to mind the so-called "Pinwheel Nebulae" that Peter had discovered 20 years ago, but this was larger and with more complicated structure than the clean Archimedean spiral observed in those systems."
^Callingham 2018,"We wrote a proposal to use a mid-infrared camera on the European Southern Observatory’s Very Large Telescope (VLT) to image the source in the middle of my PhD..."
^Callingham et al. 2018,page 1, "Near-critical stellar rotation is known to drive such winds, suggesting this Wolf-Rayet system as a potential Galactic progenitor system to long-duration gamma-ray bursts."
.jpg)
