Long-period Pulsars as Possible Outcomes of Supernova Fallback Accretion

Ronchi, M.; Rea, N.; Graber, Vanessa; Hurley‐Walker, N.

doi:10.3847/1538-4357/ac7cec

Cited by 20 publications

(35 citation statements)

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“…In this case, to explain the 18 min spin period, we would need a constant field of B ∼ 10 15 G for ∼10 8 yr (or B ∼ 10 16 G for ∼10 6 yr), which is rather extreme when compared to the known magnetar population in our Galaxy. In contrast, assuming fall-back accretion, the spin period can easily be reconciled with a 18 min value (Ronchi et al 2022). Although the core-dominated field-decay interpretation or a fast cooling scenario are in principle viable, they are intriguing, as we have no evidence of other pulsars that require either hypothesis to explain their emission and spin period.…”

Section: Discussionmentioning

confidence: 79%

“…In the magnetar scenario, the upper limits we have derived on the X-ray luminosity (L X < 10 30 erg s −1 ) imply that GLEAM-X J1627's age should be >1 Myr for any reasonable crustal magnetic field (B > 10 13 G). The 18 min spin period (assuming a fast rotating pulsar at birth) would necessarily require a strong magnetic field and a phase of fossil-disk accretion (see Ronchi et al 2022), but in any case the age of GLEAM-X J1627 is constrained to be two orders of magnitude higher than that of typical radio-loud magnetars (which have ages <20 kyr). At this age, the bright radio bursts emitted by GLEAM-X J1627 would be unusual for such an old magnetar.…”

Section: Discussionmentioning

confidence: 99%

Section: The Transient Periodic Radio Emission In the Framework Of Ra...mentioning

confidence: 99%

“…However, as extensively studied by Ronchi et al (2022), the 18 min periodicity of GLEAM-X J1627's radio emission cannot be reconciled with the pulsar scenario when only dipolar losses and a typical crust+core field configuration are considered. This would require the assumption that this pulsar has an unreasonably large magnetic field (B ∼ 10 16 -10 17 G) that does not decay in time (something unseen in the pulsar population; see also Figure 1 by Ronchi et al 2022). In a typical crust+core field configuration, the magnetic field is expected to decay on a timescale of 10-100 Kyr depending on its intensity (the stronger the field, the faster it decays; see the spin-period evolutionary curves in Figure 1).…”

Section: The Transient Periodic Radio Emission In the Framework Of Ra...mentioning

confidence: 99%

“…In this scenario, the supernova fossil-disk is now inactive (because the disk is now too cold or has been completely disrupted), so the source had resumed its dipolar-driven rotation and normal radio-loud magnetar activity. However, its spin period has been driven at a longer value than that of its peers at the same age and field (∼10 14 -10 15 G; for detailed simulations, see Ronchi et al 2022;Gençali et al 2022, andTong 2022).…”

Section: The Transient Periodic Radio Emission In the Framework Of Ra...mentioning

confidence: 99%

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Constraining the Nature of the 18 min Periodic Radio Transient GLEAM-X J162759.5-523504.3 via Multiwavelength Observations and Magneto-thermal Simulations

Rea

Zelati

Dehman

et al. 2022

ApJ

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We observed the periodic radio transient GLEAM-X J162759.5-523504.3 (GLEAM-X J1627) using the Chandra X-ray Observatory for about 30 ks on 2022 January 22–23, simultaneously with radio observations from the Murchison Widefield Array, MeerKAT, and the Australia Telescope Compact Array. Its radio emission and 18 min periodicity led the source to be tentatively interpreted as an extreme magnetar or a peculiar highly magnetic white dwarf. The source was not detected in the 0.3–8 keV energy range with a 3σ upper limit on the count rate of 3 × 10−4 counts s−1. No radio emission was detected during our X-ray observations either. Furthermore, we studied the field around GLEAM-X J1627 using archival European Southern Observatory and DECam Plane Survey data, as well as recent Southern African Large Telescope observations. Many sources are present close to the position of GLEAM-X J1627, but only two within the 2″ radio position uncertainty. Depending on the assumed spectral distribution, the upper limits converted to an X-ray luminosity of L X < 6.5 × 1029 erg s−1 for a blackbody with temperature kT = 0.3 keV, or L X < 9 × 1029 erg s−1 for a power law with photon index Γ = 2 (assuming a 1.3 kpc distance). Furthermore, we performed magneto-thermal simulations for neutron stars considering crust- and core-dominated field configurations. Based on our multiband limits, we conclude that (i) in the magnetar scenario, the X-ray upper limits suggest that GLEAM-X J1627 should be older than ∼1 Myr, unless it has a core-dominated magnetic field or has experienced fast cooling; (ii) in the white dwarf scenario, we can rule out most binary systems, a hot sub-dwarf, and a hot magnetic isolated white dwarf (T ≳ 10.000 K), while a cold isolated white dwarf is still compatible with our limits.

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Section: Discussionmentioning

confidence: 79%

Section: Discussionmentioning

confidence: 99%

Section: The Transient Periodic Radio Emission In the Framework Of Ra...mentioning

confidence: 99%

Section: The Transient Periodic Radio Emission In the Framework Of Ra...mentioning

confidence: 99%

Section: The Transient Periodic Radio Emission In the Framework Of Ra...mentioning

confidence: 99%

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Constraining the Nature of the 18 min Periodic Radio Transient GLEAM-X J162759.5-523504.3 via Multiwavelength Observations and Magneto-thermal Simulations

Rea

Zelati

Dehman

et al. 2022

ApJ

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Enigma of GLEAM-X J162759.5–523504.3

Konar

2023

J Astrophys Astron

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Early accretion onset in long-period isolated pulsars

Afonina,

Biryukov,

Popov

2024

Publ. Astron. Soc. Aust.

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We model long-term magneto-rotational evolution of isolated neutron stars with long initial spin periods. This analysis is motivated by the recent discovery of young long-period neutron stars observed as periodic radio sources: PSR J0901-4046, GLEAM-X J1627-52, and GPM J1839-10. Our calculations demonstrate that for realistically rapid spin-down during the propeller stage isolated neutron stars with velocities ≲ 100 km s–1 and assumed long initial spin periods can reach the stage of accretion from the interstellar medium within at most a few billion years as they are born already at the propeller stage or sufficiently close to the critical period of the ejector-propeller transition. If neutron stars with long initial spin periods form a relatively large fraction of all Galactic neutron stars then the number of isolated accretors is substantially larger than it has been predicted by previous studies.

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Long-period Pulsars as Possible Outcomes of Supernova Fallback Accretion

Cited by 20 publications

References 104 publications

Constraining the Nature of the 18 min Periodic Radio Transient GLEAM-X J162759.5-523504.3 via Multiwavelength Observations and Magneto-thermal Simulations

Constraining the Nature of the 18 min Periodic Radio Transient GLEAM-X J162759.5-523504.3 via Multiwavelength Observations and Magneto-thermal Simulations

Enigma of GLEAM-X J162759.5–523504.3

Early accretion onset in long-period isolated pulsars

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