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The MeerKAT telescope as a pulsar facility: System verification and early science results from MeerTime

Bailes, M. ; Jameson, A. ; Abbate, F. ; [et al.]

Cambridge University Press (CUP) ; 2020

In: Publications of the Astronomical Society of Australia Vol. 37 ( 2020)

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In: Publications of the Astronomical Society of Australia, Cambridge University Press (CUP), Vol. 37 ( 2020)

Abstract: We describe system verification tests and early science results from the pulsar processor (PTUSE) developed for the newly commissioned 64-dish SARAO MeerKAT radio telescope in South Africa. MeerKAT is a high-gain ( ${\sim}2.8\,\mbox{K Jy}^{-1}$ ) low-system temperature ( ${\sim}18\,\mbox{K at }20\,\mbox{cm}$ ) radio array that currently operates at 580–1 670 MHz and can produce tied-array beams suitable for pulsar observations. This paper presents results from the MeerTime Large Survey Project and commissioning tests with PTUSE. Highlights include observations of the double pulsar $\mbox{J}0737{-}3039\mbox{A}$ , pulse profiles from 34 millisecond pulsars (MSPs) from a single 2.5-h observation of the Globular cluster Terzan 5, the rotation measure of Ter5O, a 420-sigma giant pulse from the Large Magellanic Cloud pulsar PSR $\mbox{J}0540{-}6919$ , and nulling identified in the slow pulsar PSR J0633–2015. One of the key design specifications for MeerKAT was absolute timing errors of less than 5 ns using their novel precise time system. Our timing of two bright MSPs confirm that MeerKAT delivers exceptional timing. PSR $\mbox{J}2241{-}5236$ exhibits a jitter limit of $〈4\,\mbox{ns h}^{-1}$ whilst timing of PSR $\mbox{J}1909{-}3744$ over almost 11 months yields an rms residual of 66 ns with only 4 min integrations. Our results confirm that the MeerKAT is an exceptional pulsar telescope. The array can be split into four separate sub-arrays to time over 1 000 pulsars per day and the future deployment of S-band (1 750–3 500 MHz) receivers will further enhance its capabilities.

Type of Medium: Online Resource

ISSN: 1323-3580 , 1448-6083

URL: Article

DOI: 10.1017/pasa.2020.19

Language: English

Publisher: Cambridge University Press (CUP)

Publication Date: 2020

detail.hit.zdb_id: 2560489-2

detail.hit.zdb_id: 2079225-6

SSG: 16,12

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TRAPUM discovery of 13 new pulsars in NGC 1851 using MeerKAT

Ridolfi, A. ; Freire, P. C. C. ; Gautam, T. ; [et al.]

EDP Sciences ; 2022

In: Astronomy & Astrophysics Vol. 664 ( 2022-08), p. A27-

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In: Astronomy & Astrophysics, EDP Sciences, Vol. 664 ( 2022-08), p. A27-

Abstract: We report the discovery of 13 new pulsars in the globular cluster NGC 1851 by the TRAPUM Large Survey Project using the MeerKAT radio telescope. The discoveries consist of six isolated millisecond pulsars (MSPs) and seven binary pulsars, of which six are MSPs and one is mildly recycled. For all the pulsars, we present the basic kinematic, astrometric, and orbital parameters, where applicable, as well as their polarimetric properties, when these are measurable. Two of the binary MSPs (PSR J0514−4002D and PSR J0514−4002E) are in wide and extremely eccentric ( e 〉 0.7) orbits with a heavy white dwarf and a neutron star as their companion, respectively. With these discoveries, NGC 1851 is now tied with M28 as the cluster with the third largest number of known pulsars (14). Its pulsar population shows remarkable similarities with that of M28, Terzan 5, and other clusters with comparable structural parameters. The newly found pulsars are all located in the innermost regions of NGC 1851 and will likely enable, among other things, detailed studies of the cluster structure and dynamics.

Type of Medium: Online Resource

ISSN: 0004-6361 , 1432-0746

URL: Article

DOI: 10.1051/0004-6361/202143006

RVK:

UA 1000

RVK:

US 1090

Language: English

Publisher: EDP Sciences

Publication Date: 2022

detail.hit.zdb_id: 1458466-9

SSG: 16,12

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PSR J1910–5959A: A rare gravitational laboratory for testing white dwarf models

Corongiu, A. ; Venkatraman Krishnan, V. ; Freire, P. C. C. ; [et al.]

EDP Sciences ; 2023

In: Astronomy & Astrophysics Vol. 671 ( 2023-03), p. A72-

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In: Astronomy & Astrophysics, EDP Sciences, Vol. 671 ( 2023-03), p. A72-

Abstract: Context. PSR J1910−5959A is a binary millisecond pulsar in a 0.837 day circular orbit around a helium white dwarf (HeWD) companion. The position of this pulsar is 6.3 arcmin (∼74 core radii) away from the optical centre of the globular cluster (GC) NGC 6752. Given the large offset, the association of the pulsar with the GC has been debated. Aims. We aim to obtain precise measurements of the masses of the stars in the system along with secular orbital parameters, which will help identify if the system belongs to the GC. Methods. We have made use of archival Parkes 64 m ‘Murriyang’ telescope data and carried out observations with the MeerKAT telescope with different backends and receivers over the last two decades. Pulse times of arrival were obtained from these using standard pulsar data reduction techniques and analysed using state-of-the-art Bayesian pulsar timing techniques. We also performed an analysis of the pulsar’s total intensity and polarisation profile to understand the interstellar scattering along the line of sight, and we determined the pulsar’s geometry by fitting the rotating vector model to the polarisation data. Results. We obtain precise measurements of several post-Keplerian parameters: the range, r = 0.202(6) T ⊙ , and shape, s = 0.999823(4), of the Shapiro delay, from which we infer: the orbital inclination to be 88.9 −0.14 +0.15 deg; the masses of the pulsar and the companion to be 1.55(7) M ⊙ and 0.202(6) M ⊙ , respectively; a secular change in the orbital period Ṗ b = −53 −6.0 +7.4 × 10 −15 s s −1 that proves the GC association; and a secular change in the projected semi-major axis of the pulsar, ẋ = −40.7 −8.2 +7.3 × 10 −16 s s −1 , likely caused by the spin–orbit interaction from a misaligned HeWD spin, at odds with the likely isolated binary evolution of the system. We also discuss some theoretical models for the structure and evolution of white dwarfs in neutron star–white dwarf binaries, using PSR J1910−5959A’s companion as a test bed. Conclusions. PSR J1910−5959A is a rare system for which several parameters of both the pulsar and the HeWD companion can be accurately measured. As such, it is a test bed for discriminating between alternative models of HeWD structure and cooling.

Type of Medium: Online Resource

ISSN: 0004-6361 , 1432-0746

URL: Article

DOI: 10.1051/0004-6361/202244418

RVK:

UA 1000

RVK:

US 1090

Language: English

Publisher: EDP Sciences

Publication Date: 2023

detail.hit.zdb_id: 1458466-9

SSG: 16,12

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Mass measurements and 3D orbital geometry of PSR J1933–6211

Geyer, M. ; Venkatraman Krishnan, V. ; Freire, P. C. C. ; [et al.]

EDP Sciences ; 2023

In: Astronomy & Astrophysics Vol. 674 ( 2023-06), p. A169-

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In: Astronomy & Astrophysics, EDP Sciences, Vol. 674 ( 2023-06), p. A169-

Abstract: PSR J1933−6211 is a pulsar with a spin period of 3.5 ms in a 12.8 d nearly circular orbit with a white dwarf companion. Its high proper motion and low dispersion measure result in such significant interstellar scintillation that detections with a high signal-to-noise ratio have required long observing durations or fortuitous timing. In this work, we turn to the sensitive MeerKAT telescope, and combined with historic Parkes data, are able to leverage the kinematic and relativistic effects of PSR J1933−6211 to constrain its 3D orbital geometry and the component masses. We obtain a precise proper motion magnitude of 12.42 (3) mas yr −1 and a parallax of 1.0 (3) mas, and we also measure their effects as secular changes in the Keplerian parameters of the orbit: a variation in the orbital period of 7 (1)×10 −13 s s −1 and a change in the projected semi-major axis of 1.60 (5)×10 −14 s s −1 . A self-consistent analysis of all kinematic and relativistic effects yields a distance to the pulsar of $ 1.6^{+0.2}_{-0.3} $ kpc, an orbital inclination, i = 55 (1) deg, and a longitude of the ascending node, $ \Omega = 255^{+8}_{-14} $ deg. The probability densities for Ω and i and their symmetric counterparts, 180 − i and 360 − Ω, are seen to depend on the chosen fiducial orbit used to measure the time of passage of periastron ( T 0 ). We investigate this unexpected dependence and rule out software-related causes using simulations. Nevertheless, we constrain the masses of the pulsar and its companion to be $ 1.4^{+0.3}_{-0.2}\,M_\odot $ and 0.43 (5) M ⊙ , respectively. These results strongly disfavour a helium-dominated composition for the white dwarf companion. The similarity in the spin, orbital parameters, and companion masses of PSRs J1933−6211 and J1614−2230 suggests that these systems underwent case A Roche-lobe overflow, an extended evolutionary process that occurs while the companion star is still on the main sequence. However, PSR J1933−6211 has not accreted significant matter: its mass is still at ∼1.4 M ⊙ . This highlights the low accretion efficiency of the spin-up process and suggests that observed neutron star masses are mostly a result of supernova physics, with minimum influence of subsequent binary evolution.

Type of Medium: Online Resource

ISSN: 0004-6361 , 1432-0746

URL: Article

DOI: 10.1051/0004-6361/202244654

RVK:

UA 1000

RVK:

US 1090

Language: English

Publisher: EDP Sciences

Publication Date: 2023

detail.hit.zdb_id: 1458466-9

SSG: 16,12

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The eccentric millisecond pulsar, PSR J0955−6150 : I. Pulse profile analysis, mass measurements, and constraints on binary evolution

Serylak, M. ; Venkatraman Krishnan, V. ; Freire, P. C. C. ; [et al.]

EDP Sciences ; 2022

In: Astronomy & Astrophysics Vol. 665 ( 2022-09), p. A53-

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In: Astronomy & Astrophysics, EDP Sciences, Vol. 665 ( 2022-09), p. A53-

Abstract: Context. PSR J0955−6150 is a member of an enigmatic class of eccentric millisecond pulsar (MSP) and helium white dwarf (He WD) systems (eMSPs), whose binary evolution is poorly understood and believed to be strikingly different to that of traditional MSP+He WD systems in circular orbits. Aims. Measuring the masses of the stars in this system is important for testing the different hypotheses for the formation of eMSPs. Methods. We carried out timing observations of this pulsar with the Parkes radio telescope using the 20 cm multibeam and ultra-wide bandwidth low-frequency (UWL) receivers, and the L -band receiver of the MeerKAT radio telescope. The pulse profiles were flux and polarisation calibrated, and a rotating-vector model (RVM) was fitted to the position angle of the linear polarisation of the combined MeerKAT data. Pulse times of arrival (ToAs) were obtained from these using standard pulsar analysis techniques and analysed using the TEMPO 2 timing software. Results. Our observations reveal a strong frequency evolution of this MSP’s intensity, with a flux density spectral index ( α ) of −3.13(2). The improved sensitivity of MeerKAT resulted in a greater than tenfold improvement in the timing precision obtained compared to our older Parkes observations. This, combined with the eight-year timing baseline, has allowed precise measurements of a very small proper motion and three orbital post-Keplerian parameters, namely the rate of advance of periastron, ω̇ = 0.00152(1) deg yr −1 , and the orthometric Shapiro delay parameters, h 3 = 0.89(7) μs and ς = 0.88(2). Assuming general relativity, we obtain M p = 1.71(2) M ⊙ for the mass of the pulsar and M c = 0.254(2) M ⊙ for the mass of the companion; the orbital inclination is 83.2(4) degrees. Crucially, assuming that the position angle of the linear polarisation follows the RVM, we find that the spin axis has a misalignment relative to the orbital angular momentum of 〉 4.8deg at 99% confidence level. Conclusions. While the value of M p falls well within the wide range observed in eMSPs, M c is significantly smaller than expected from several formation hypotheses proposed, which are therefore unlikely to be correct and can be ruled out; M c is also significantly different from the expected value for an ideal low mass X-ray binary evolution scenario. If the misalignment between the spin axis of the pulsar and the orbital angular momentum is to be believed, it suggests that the unknown process that created the orbital eccentricity of the binary was also capable of changing its orbital orientation, an important evidence for understanding the origin of eMSPs.

Type of Medium: Online Resource

ISSN: 0004-6361 , 1432-0746

URL: Article

DOI: 10.1051/0004-6361/202142670

RVK:

UA 1000

RVK:

US 1090

Language: English

Publisher: EDP Sciences

Publication Date: 2022

detail.hit.zdb_id: 1458466-9

SSG: 16,12

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