Vela Pulsar Explained

The Vela Pulsar (PSR J0835-4510 or PSR B0833-45) is a radio, optical, X-ray- and gamma-emitting pulsar associated with the Vela Supernova Remnant in the constellation of Vela. Its parent Type II supernova exploded approximately 11,000–12,300 years ago (and was about 800 light-years away).

Characteristics

Vela is the brightest pulsar (at radio frequencies) in the sky and spins 11 times per second (i.e. a period of 89.33 milliseconds—the shortest known at the time of its discovery) and the remnant from the supernova explosion is estimated to be travelling outwards at 1200km/s. It has the third-brightest optical component of all known pulsars (V = 23.6 mag) which pulses twice for every single radio pulse. The Vela pulsar is the brightest persistent object in the high-energy gamma-ray sky.

Pulsed emission up to 20 TeV has been detected from the Vela pulsar and together with the Crab pulsar at 1.5 TeV^[1] are the only two known pulsar with emission in this energy range^[2]

Glitches

Glitches are sudden spin-ups in the rotation of pulsars. Vela is the best known of all the glitching pulsars, with glitches occurring on average every three years. Glitches are currently not predictable.

On 12 December 2016, Vela was observed to glitch live for the first time with a radio telescope (the 26 m telescope at the Mount Pleasant Radio Observatory) large enough to see individual pulses. This observation showed that the pulsar nulled (i.e. did not pulse) for one pulse, with the pulse prior being very broad and the two following pulses featuring low linear polarization. It also appeared that the glitch process took under five seconds to occur and allowed to estimate physical properties of the pulsar.^{[3] [4]}

On 22 July 2021, a new glitch occurred. As a result, the period of the pulsar decreased by about 1 part in a million.^[5]

Statistically, nearly the 1% of the long-term spin-down of the pulsar is reversed in spin-up glitches, a fraction that is also observed in other monitored pulsars.^[6] Careful estimation of the glitch activity and its uncertainty requires statistical tools beyond the simple linear regression.^[7]

Research campaigns

The association of the Vela pulsar with the Vela Supernova Remnant, made by astronomers at the University of Sydney in 1968, was direct observational proof that supernovae form neutron stars.

Studies conducted by Kellogg et al. with the Uhuru spacecraft in 1970–71 showed the Vela pulsar and Vela X to be separate but spatially related objects. The term Vela X was used to describe the entirety of the supernova remnant. Weiler and Panagia established in 1980 that Vela X was actually a pulsar wind nebula, contained within the fainter supernova remnant and driven by energy released by the pulsar.

Nomenclature

The pulsar is occasionally referred to as Vela X, but this phenomenon is separate from either the pulsar or the Vela X nebula. A radio survey of the Vela-Puppis region was made with the Mills Cross Telescope in 1956–57 and identified three strong radio sources: Vela X, Vela Y, and Vela Z. These sources are observationally close to the Puppis A supernova remnant, which is also a strong X-ray and radio source.

Neither the pulsar nor either of the associated nebulae should be confused with Vela X-1, an observationally close but unrelated high-mass X-ray binary system.

In music

The emissions of Vela and the pulsar PSR B0329+54 were converted into audible sound by French composer Gérard Grisey and used in the piece Le noir de l'étoile (1989–90).

External links

• Vela Pulsar at SIMBAD
• Vela Pulsar at NASA/IPAC Extragalactic Database

Notes and References

1. The H.E.S.S. Collaboration . etal . Aharonian . F. . Benkhali . F. Ait . Aschersleben . J. . Ashkar . H. . Backes . M. . Martins . V. Barbosa . Batzofin . R. . Becherini . Y. . Berge . D. . Bernlöhr . K. . Bi . B. . Böttcher . M. . Boisson . C. . Bolmont . J. . 2023-10-05 . Discovery of a radiation component from the Vela pulsar reaching 20 teraelectronvolts . Nature Astronomy . en . 10.1038/s41550-023-02052-3 . 2397-3366. 2310.06181 .
2. The H.E.S.S. Collaboration . Aharonian . F. . Benkhali . F. Ait . Aschersleben . J. . Ashkar . H. . Backes . M. . Martins . V. Barbosa . Batzofin . R. . Becherini . Y. . Berge . D. . Bernlöhr . K. . Bi . B. . Böttcher . M. . Boisson . C. . Bolmont . J. . 2023-10-05 . Discovery of a radiation component from the Vela pulsar reaching 20 teraelectronvolts . Nature Astronomy . en . 10.1038/s41550-023-02052-3 . 2397-3366. 2310.06181 .
3. Web site: Ashton . G. . Rotational evolution of the Vela pulsar during the 2016 glitch .
4. Montoli . Alessandro . Antonelli . Marco . Magistrelli . Fabio . Pizzochero . Pierre . October 2020 . Bayesian estimate of the superfluid moments of inertia from the 2016 glitch in the Vela pulsar . Astronomy & Astrophysics . 642 . A223 . 10.1051/0004-6361/202038340 . 0004-6361. free . 2005.01594 .
5. Web site: A new Glitch in the Vela Pulsar (PSR B0833-45/PSR J0835-4510). The Astronomer's Telegram. 23 July 2021. V. Sosa-Fiscella. E. Zubieta. S. del Palacio. F. Garcia. F. A. Lopez-Armengol. J. A. Combi. C. O. Lousto. G. Gancio. L. Combi. E. Gutierrez. A. Simaz Bunzel. F. Hauscarriaga. 4. 24 July 2021.
6. McKenna . J. . Lyne . A. G. . January 1990 . PSR1737–30 and period discontinuities in young pulsars . Nature . en . 343 . 6256 . 349–350 . 10.1038/343349a0 . 1476-4687.
7. Montoli . Alessandro . Antonelli . Marco . Haskell . Brynmor . Pizzochero . Pierre . 2021-01-05 . Statistical estimates of the pulsar glitch activity . Universe . 7 . 1 . 8 . 10.3390/universe7010008 . 2218-1997. free . 2434/903235 . free .