Your search keyword '"BINARY pulsars"' showing total 1,082 results

1. Ultraluminous X-ray sources with He star companions.

Author

Li, Luhan, Wang, Bo, Liu, Dongdong, Guo, Yunlang, Chen, Wen-Cong, and Han, Zhanwen

Subjects

*STELLAR evolution, *SUPERGIANT stars, *STARS, *EDDINGTON mass limit, *ROCHE equipotentials, *BINARY pulsars

Abstract

Ultraluminous X-ray sources (ULXs) are non-nuclear point-like objects observed with extremely high X-ray luminosity that exceeds the Eddington limit of a |$\rm 10\, M_\odot$| black hole. A fraction of ULXs has been confirmed to contain neutron star (NS) accretors due to the discovery of their X-ray pulsations. The donors detected in NS ULXs are usually luminous massive stars because of the observational biases. Recently, the He donor star in NGC 247 ULX-1 has been identified, which is the first evidence of a He donor star in ULXs. In this paper, we employed the stellar evolution code mesa (Modules for Experiments in Stellar Astrophysics) to investigate the formation of ULXs through the NS+He star channel, in which a He star transfers its He-rich material onto the surface of an NS via Roche lobe overflow. We evolved a large number of NS+He star systems and provided the parameter space for the production of ULXs. We found that the initial NS+He star systems should have |$\sim 0.7\!-\!2.6 \, \mathrm{M}_\odot$| He star and |$\sim 0.1\!-\!2500\, \mathrm{d}$| orbital period for producing ULXs, eventually evolving into intermediate-mass binary pulsars. According to binary population synthesis calculations, we estimated that the Galactic rate of NS ULXs with He donor stars is in the range of |$\sim 1.6\!-\!4.0\times 10^{-4}\, {\rm yr}^{-1}$|⁠ , and that there exist |$\sim 7-20$| detectable NS ULXs with He donor stars in the Galaxy. [ABSTRACT FROM AUTHOR]

Published

2024

2. Optical and X-ray studies of the Be/X-ray binary IGR J06074+2205.

Author

Chhotaray, Birendra, Naik, Sachindra, Jaisawal, Gaurava K, and Ahuja, Goldy

Subjects

*CIRCUMSTELLAR matter, *BINARY pulsars, *LIGHT curves, *NEUTRON stars, *BINARY stars, *X-ray binaries

Abstract

We present the results obtained from X-ray and optical analysis of the Be/X-ray binary IGR J06074+2205, focusing on before, during, and after the X-ray outbursts in 2023 October and December. The properties of the neutron star in the binary are investigated using NICER and NuSTAR observations during the X-ray outbursts. The pulse profiles across a broad energy range, are found to be strongly dependent on luminosity and energy, revealing the complex nature of the emitting region. An absorbed power law can describe each NICER spectrum in the 1–7 keV band. The 3–79 keV NuSTAR spectrum can be well described by a negative and positive power law with an exponential cut-off model. Utilizing the MAXI/GSC long-term light curve, we estimate the probable orbital period to be 80 or 80/n (n = 2, 3, 4) d. We investigate the evolution of the circumstellar disc around the Be star by using optical spectroscopic observations of the system between 2022 and 2024. We observe variable H  |$\alpha$| and Fe  ii emission lines with an increase in equivalent width, indicating the presence of a dynamic circumstellar disc. A distinct variation in the V/R value for H  |$\alpha$| and Fe  ii lines is also observed. The appearance of additional emission lines, such as He  i (5875.72 Å), He  i (6678 Å), and He  i (7065 Å), during the post-outburst observation in 2024 February suggests the growing of a larger or denser circumstellar disc. The disc continues to grow without any noticeable mass-loss, even during the 2023 X-ray outbursts, which may lead to a future giant X-ray outburst. [ABSTRACT FROM AUTHOR]

Published

2024

3. Probing the energy and luminosity-dependent spectro-timing properties of RX J0440.9+4431 with AstroSat.

Author

Sharma, Rahul, Mandal, Manoj, Pal, Sabyasachi, Paul, Biswajit, Jaisawal, G K, and Ratheesh, Ajay

Subjects

*STELLAR magnetic fields, *BINARY pulsars, *NEUTRON stars, *ACCRETION disks, *PULSARS

Abstract

The Be/X-ray binary pulsar RX J0440.9+4431 went through a giant outburst in December 2022 with a peak flux of |$\sim$| 2.3 Crab in 15–50 keV. We studied the broad-band timing and spectral properties of RX J0440.9+4431 using four AstroSat observations, where the source transited between subcritical and supercritical accretion regimes. Pulsations were detected significantly above 100 keV. The pulse profiles were found to be highly luminosity- and energy-dependent. A significant evolution in the pulse profile shape near the peak of the outburst indicates a possible change in the accretion mode and beaming patterns of RX J0440.9+4431. The rms pulsed fraction was luminosity- and energy-dependent, with a concave-like feature around 20–30 keV. The depth of this feature varied with luminosity, indicating changes in the accretion column height and proportion of reflected photons. The broad-band continuum spectra were best fitted with a two-component Comptonization model with a blackbody component or a two-blackbody component model with a thermal Comptonization component. A quasi-periodic oscillation (QPO) at 60 mHz was detected at a luminosity of |$2.6 \times 10^{37}$|  erg s |$^{-1}$|⁠ , which evolved into 42 mHz at |$1.5 \times 10^{37}$|  erg s |$^{-1}$|⁠. The QPO rms were found to be energy dependent with an overall increasing trend with energy. For the first time, we found the QPO frequency varying with photon energy in an X-ray pulsar, which poses a challenge in explaining the QPO with current models such as the Keplarian and beat frequency model. Hence, more physically motivated models are required to understand the physical mechanism behind the mHz QPOs. [ABSTRACT FROM AUTHOR]

Published

2024

4. Investigating the equation-of-state, stability and mass–radius relationship of anisotropic and massive neutron stars embedded in f(R,T) modified gravity.

Author

Bandyopadhyay, Mayukh and Biswas, Ritabrata

Subjects

*STELLAR structure, *COMPACT objects (Astronomy), *SUPERGIANT stars, *BINARY pulsars, *NUCLEAR matter

Abstract

In this study, our main focus is to investigate the mass–radius relation and several important properties of massive neutron stars to realize the nature, behavior and evolution of these kinds of compact objects at present time. Also, we want to understand the equation-of-state of the core nuclear matter precisely with their stable equilibrium configuration. We have chosen a few massive binary pulsars and investigated on maximum attainable mass and lowest possible radius of them. We have considered Einstein–Hilbert action as f (R , T) = R + α T , where R is the Ricci scalar and T , the trace of energy–momentum tensor with α as the coupling parameter and also used modified TOV equations. The interior space-time of the spherical neutron star is matched to the exterior Schwarzschild line element at the surface of the star. The M – R curve can predict the maximum achievable mass is about 3. 5 1 M ⊙ with lowest possible radius of around 1 0. 5 km for the massive compact stars under stable equilibrium. We have obtained a clear picture of structural evolution of massive neutron stars through accelerating space-time and can put some constraints on several quantities related to them. It is depicted from our present investigation that all the derived outcomes are compatible with physically adopted regimes which reveal the viability of our current model in the context of f (R , T) modified gravity. [ABSTRACT FROM AUTHOR]

Published

2024

5. Spin evolution of neutron stars in transient low-mass X-ray binaries.

Author

Cui, Zhe and Li, Xiang-Dong

Subjects

*NEUTRON stars, *STELLAR evolution, *BINARY pulsars, *LOW mass stars, *MASS transfer

Abstract

Millisecond pulsar + helium white dwarf (MSP + He WD) binaries are thought to have descended from neutron star low-mass X-ray binaries (NS LMXBs). The NSs accreted from the progenitors of the WDs and their spin periods were accordingly accelerated to the equilibrium periods of order milliseconds. Thus, the initial spin periods of the 'recycled' NSs are critically determined by the average mass transfer rate in the LMXB phase. However, the standard picture neglects the possible spin-down of the NSs when the donor star decouples from its Roche lobe at the end of the mass transfer, as well as the transient behaviour of most LMXBs. Both imply more complicated spin evolution during the recycling process. In this work, we perform detailed calculations of the formation of MSP + He WD binaries. We take into account three magnetic braking (MB) prescriptions proposed in the literature, and examine the effects of both persistent and transient accretion. We find that the spin periods are not sensitively dependent on the efficiency of MB, but are considerably influenced by the accretion mode. In comparison with persistent accretion, transient accretion leads to shorter and longer spin periods of the NSs in narrow and wide systems, respectively. This may help account for the measured spin periods of MSPs in wide binaries, which seem to be longer than predicted by the persistent accretion model. [ABSTRACT FROM AUTHOR]

Published

2024

6. Hydrodynamical simulations of wind interaction in spider systems: A step toward understanding transitional millisecond pulsars.

Author

Guerra, C., Meliani, Z., and Voisin, G.

Subjects

*STELLAR winds, *BINARY pulsars, *WIND speed, *STARS, *ACCRETION disks, *X-ray binaries

Abstract

Context. The detected population of "spiders", referring to millisecond pulsar binaries, has significantly grown in the past decade thanks to multiwavelength follow-up investigations of unidentified Fermi sources. These systems consist of low-mass stellar companions orbiting rotation-powered millisecond pulsars in short periods of a few hours up to day. Among them, a subset of intriguing objects called transitional millisecond pulsars (tMSPs) has been shown to exhibit a remarkable behavior, transitioning between pulsar-binary and faint low-mass X-ray binary states over a span of a few years. Aims. Our objective is to study the interaction of stellar winds in tMSPs in order to understand their observational properties. To this end we focus on the parameter range that places the system near Roche-lobe overflow. Methods. Employing the adaptative mesh refinement (AMR) AMRVAC 2.0 code, we performed 2D hydrodynamical (HD) simulations of the interaction between the flows from both stars, accounting for the effects of gravity and orbital motion. Results. By studying the mass loss and launch speed of the winds, we successfully recreated two phenomenologically distinct regimes: the accretion stream and the pulsar radio state. We also identified the tipping point that marks the sharp transition between these two states. In the accretion stream state, we discover a very strong variability induced by the pulsar wind. In the pulsar state, we reconstructed the corresponding X-ray light curves of the system that produces the characteristic double-peak pattern of these systems. The position of the peaks is shifted due to orbital motion and the leading peak is weaker due to eclipsing by the companion. Conclusions. This study highlights the importance of gravity and orbital motion in the interaction between the companion and pulsar winds. Our setup allows the study of the complex interaction between the pulsar wind and an accretion stream during mass transfer. We suggest that a smaller leading peak in X-rays is indicative of a nearly edge-on system. [ABSTRACT FROM AUTHOR]

Published

2024

7. Irradiation effect and binary radio pulsars with giant companions.

Author

Lan, Shunyi and Meng, Xiangcun

Subjects

*GIANT stars, *STELLAR evolution, *NEUTRON stars, *BLACK holes, *X-ray binaries, *BINARY pulsars

Abstract

Context. Pulsars are neutron stars that rotate rapidly. Most of the pulsars in binary systems tend to spin faster than those in isolation. According to binary evolution theory, radio pulsars in binary systems can have various types of companion stars. However, binary radio pulsars with giant stars, helium stars, and black holes as companions are lacking so far. Aims. We aim to investigate the possible parameter space of binary radio pulsars with giant companions. Methods. We used the MESA stellar evolution code to consider the effect of irradiation in binary evolution and evolved a series of binary models. Results. We present the potential physical properties of binary radio pulsars with giant star companions in the framework of the classical recycling scenario and the irradiation model. We found that the parameter space of binary radio pulsars with giant companions can be greatly expanded by the effect of irradiation. Moreover, when irradiation is strong enough, submillisecond pulsars might be accompanied by giant companion stars. We also demonstrate a correlation between the timescale of the binary system as a low-mass X-ray binary and the irradiation efficiency. Conclusions. The birthrate problem between millisecond pulsars and low-mass X-ray binaries might not be resolved by the irradiation effect. A more detailed binary population synthesis is necessary. Our findings may offer guidance for observers that wish to locate binary radio pulsars with giant companions or submillisecond pulsars. [ABSTRACT FROM AUTHOR]

Published

2024

8. Cramér-Rao lower bounds on parameter estimation for a circular binary of supermassive black holes in gravitational wave observations using pulsar timing array.

Author

Duan, Qing-Qing, Liu, Jin, and Kang, Zhi-Wei

Subjects

*BINARY black holes, *PARAMETER estimation, *GRAVITATIONAL waves, *TIME management, *BINARY pulsars, *SIGNAL-to-noise ratio, *SUPERMASSIVE black holes, PULSAR detection

Abstract

Pulsar timing arrays (PTAs) are effective in detecting low-frequency gravitational waves (GWs), especially in circular binary systems of supermassive black holes. To evaluate the effectiveness and accuracy of PTAs in searching for GW parameter estimation, we use the Cramer-Rao lower bound to estimate the parameters of the Virgo source under various search conditions, including both evolving and non-evolving scenarios, as well as Earth and pulsar term searches, and only Earth term searches. The results show that the estimation accuracy of the inclination angle and GW strain is lower in the evolving condition than in the non-evolving condition because the two parameters participate in the evolving process. In addition, we find that the parameters estimable relates to signal-to-noise ratio, which is beneficial for reducing the dimensionality in the search process. In summary, our method serves as a reference for exploring lower parameter limits under different conditions and assists in assessing the optimization of parameter estimation in GW detection algorithms. This helps lay the theoretical foundation for advances in the field of GWs and the optimization of PTAs. [ABSTRACT FROM AUTHOR]

Published

2024

9. Gravity experiments with radio pulsars.

Author

Freire, Paulo C. C. and Wex, Norbert

Subjects

*PULSARS, *BINARY pulsars, *BINARY stars, *GRAVITATIONAL interactions, *GRAVITATIONAL waves, *LORENTZ invariance

Abstract

The discovery of the first pulsar in a binary star system, the Hulse–Taylor pulsar, 50 years ago opened up an entirely new field of experimental gravity. For the first time it was possible to investigate strong-field and radiative aspects of the gravitational interaction. Continued observations of the Hulse–Taylor pulsar eventually led, among other confirmations of the predictions of general relativity (GR), to the first evidence for the reality of gravitational waves. In the meantime, many more radio pulsars have been discovered that are suitable for testing GR and its alternatives. One particularly remarkable binary system is the Double Pulsar, which has far surpassed the Hulse–Taylor pulsar in several respects. In addition, binary pulsar-white dwarf systems have been shown to be particularly suitable for testing alternative gravitational theories, as they often predict strong dipolar gravitational radiation for such asymmetric systems. A rather unique pulsar laboratory is the pulsar in a hierarchical stellar triple, that led to by far the most precise confirmation of the strong-field version of the universality of free fall. Using radio pulsars, it could be shown that additional aspects of the Strong Equivalence Principle apply to the dynamics of strongly self-gravitating bodies, like the local position and local Lorentz invariance of the gravitational interaction. So far, GR has passed all pulsar tests with flying colours, while at the same time many alternative gravity theories have either been strongly constrained or even falsified. New telescopes, instrumentation, timing and search algorithms promise a significant improvement of the existing tests and the discovery of (qualitatively) new, more relativistic binary systems. [ABSTRACT FROM AUTHOR]

Published

2024

10. H.E.S.S. observations of the 2021 periastron passage of PSR B1259-63/LS 2883.

Author

Aharonian, F., Ait Benkhali, F., Aschersleben, J., Ashkar, H., Backes, M., Barbosa Martins, V., Batzofin, R., Becherini, Y., Berge, D., Bernlöhr, K., Böttcher, M., Boisson, C., Bolmont, J., de Bony de Lavergne, M., Borowska, J., Bouyahiaoui, M., Brose, R., Brown, A., Brun, F., and Bruno, B.

Subjects

*LIGHT curves, *PARTICLE acceleration, *BINARY pulsars, *ORBITS (Astronomy), *CONFIDENCE intervals

Abstract

PSR B1259–63/LS 2883 is a gamma-ray binary system that hosts a pulsar in an eccentric orbit, with a 3.4 yr period, around an O9.5Ve star (LS 2883). At orbital phases close to periastron passages, the system radiates bright and variable non-thermal emission, for which the temporal and spectral properties of this emission are, for now, poorly understood. In this regard, very high-energy (VHE) emission is especially useful to study and constrain radiation processes and particle acceleration in the system. We report on an extensive VHE observation campaign conducted with the High Energy Stereoscopic System, comprised of approximately 100 h of data taken over five months, from tp − 24 days to tp + 127 days around the system's 2021 periastron passage (where tp is the time of periastron). We also present the timing and spectral analyses of the source. The VHE light curve in 2021 is consistent overall with the stacked light curve of all previous observations. Within the light curve, we report a VHE maximum at times coincident with the third X-ray peak first detected in the 2021 X-ray light curve. In the light curve – although sparsely sampled in this time period – we see no VHE enhancement during the second disc crossing. In addition, we see no correspondence to the 2021 GeV flare in the VHE light curve. The VHE spectrum obtained from the analysis of the 2021 dataset is best described by a power law of spectral index Γ = 2.65 ± 0.04stat ± 0.04sys, a value consistent with the spectral index obtained from the analysis of data collected with H.E.S.S. during the previous observations of the source. We report spectral variability with a difference of ΔΓ = 0.56 ± 0.18stat ± 0.10sys at 95% confidence intervals, between sub-periods of the 2021 dataset. We also detail our investigation into X-ray/TeV and GeV/TeV flux correlations in the 2021 periastron passage. We find a linear correlation between contemporaneous flux values of X-ray and TeV datasets, detected mainly after tp + 25 days, suggesting a change in the available energy for non-thermal radiation processes. We detect no significant correlation between GeV and TeV flux points, within the uncertainties of the measurements, from ∼tp − 23 days to ∼tp + 126 days. This suggests that the GeV and TeV emission originate from different electron populations. [ABSTRACT FROM AUTHOR]

Published

2024

11. Temporal and spectral variations of the X-ray pulsar Cen X-3 observed by NuSTAR.

Author

Liu, Qi, Wang, Wei, Santangelo, Andrea, Kong, Lingda, Ji, Long, and Ducci, Lorenzo

Subjects

*STELLAR winds, *BINARY pulsars, *ENERGY bands, *ECLIPSING binaries, *NEUTRON stars

Abstract

We report a time-resolved analysis of the accreting X-ray pulsar Cen X-3 using observations carried out by NuSTAR, which cover approximately two binary orbits in different intensity states. The pulse profile is relatively stable over the orbital phase and shows energy dependence. It has an obvious double-peaked shape in the energy band below 15 keV –with the second pulse peak decreasing as energy increases– and is gradually dominated by a single peak in higher energy bands. We find that the pulse profile in the energy band of 3–5 keV at high-intensity states shows a subtle triple-peaked shape, with the main peak divided into two subpeaks. We also find a positive correlation between the pulse fraction and both energy and flux. Our spectral analysis reveals that the spectra can be well described by the continuum of Fermi-Dirac cutoff and NPEX models, and the cyclotron line is detected with the centroid energies varying from 26 keV to 29 keV, along with the iron emission line around 6.4 keV. We investigated the dependence between the cyclotron resonant scattering feature (CRSF) centroid energy and luminosity and discuss the theoretical critical luminosity. Although the variation of Ecyc − LX is not distinct, there is a possibility that the critical luminosity lies within the range of ∼(0.5 − 4)×1037 erg s−1 in the band of 4–78 keV. The photon index shows a strong positive correlation with luminosity. Our orbital-phase analysis reveals that the spectral parameters show orbital variability, and the highly variable photoelectric absorption may indicate the existence of clumpy stellar winds. [ABSTRACT FROM AUTHOR]

Published

2024

12. Low-luminosity accretion of Be/X-ray pulsar MAXI J1409−619.

Author

Ghimiray, Monika, Sharma, Pankaj, and Subba, Nishika

Subjects

*PULSARS, *LONG-Term Evolution (Telecommunications), *LIGHT curves, *ENERGY bands, *BINARY pulsars, *NEUTRON stars

Abstract

This paper used Nuclear Spectroscopic Telescope Array observations to examine the temporal and spectral features of the Be/X-ray binary pulsar MAXI J1409−619. The timing analysis of the light curve finds the pulsation of the source at |$(501.23\,\,\pm \,\,0.01)$|  s. The pulse profile of the source in various energy bands was analysed and showed weak dependence on energy exhibiting asymmetric character and generally suggests a source accretion in the subcritical regime. The variation of pulse fraction with photon energy in general shows an increasing trend. Assuming a distance of 14.5 kpc, we calculated the 3–30 keV source luminosity to be |$\sim 6.13\,\,\times \,\,10^{34}\,\,$|  erg s |$^{-1}$|⁠. The long-term spin evolution of the source was carried out, where the source underwent torque reversal. [ABSTRACT FROM AUTHOR]

Published

2024

13. An arcsecond view at 1–2 GHz into the Galactic Bulge.

Author

Pattie, E C, Maccarone, T J, Britt, C T, Heinke, C O, Jonker, P G, Lorimer, D R, Sivakoff, G R, Steeghs, D, Strader, J, Torres, M A P, and Wijnands, R

Subjects

*GALACTIC bulges, *ACTIVE galactic nuclei, *PLANETARY nebulae, *BINARY pulsars

Abstract

We present the results of a high angular resolution (1.1 arcsec) and sensitivity (maximum of ∼0.1 mJy) radio survey at 1–2 GHz in the Galactic Bulge. This complements the X-ray Chandra Galactic Bulge Survey, and investigates the full radio source population in this dense Galactic region. Radio counterparts to sources at other wavelengths can aid in classification, as there are relatively few types of objects that are reasonably detectable in radio at kiloparsec distances, and even fewer that are detected in both X-rays and radio. This survey covers about 3 sq deg of the Galactic Bulge Survey area (spanning the Galactic coordinate range of −3° < l < +3° and +1.6° < b < +2.1°) as a first look into this region of the Galaxy with this combination of frequency, resolution, and sensitivity. Spectral indices within the observed band of 1–2 GHz were calculated for each source to assist in determining its emission mechanism. We find 1617 unique sources in the survey, 25 of which are radio counterparts to X-ray sources, and about 100 of which are steep-spectrum (α ≲ −1.4) point sources that are viable pulsar candidates. Four radio sources are of particular interest: a compact binary; an infrared transient with an inverted radio spectrum; a potential transitional millisecond pulsar candidate; and a very steep spectrum radio source with an X-ray and bright infrared counterpart. We discuss other notable sources, including possible radio transients, potential new planetary nebulae, and active galactic nuclei. [ABSTRACT FROM AUTHOR]

Published

2024

14. On the overall properties of young neutron stars: an application to the Crab pulsar.

Author

Bernal, Cristian G., Frajuca, Carlos, Hirsch, Henrique D., Minari, Beatriz, Magalhaes, Nadja S., Selbach, Lucas B., Wen-Cong Chen, and Popov, Sergey

Subjects

*NEUTRON stars, *CRABS, *MAGNETIC fields, *SUPERNOVAE, *BINARY pulsars

Abstract

In this brief report, we present a model that complements the well-established canonical model for the spin evolution of rotation-powered pulsars, which is typically used to estimate ages, spin-down luminosity, and surface magnetic fields of middle-aged pulsars. We analytically explore the growth of the magnetic field during a pulsar's early history, a period shortly after supernova explosion from which the neutron star forms, encompassing the hypercritical phase and subsequent reemergence of the magnetic field. We analyze the impact of such growth on the early dynamics of the pulsar. Investigations into a pulsar's magnetic evolution are not new, and we expand the knowledge in this area by examining the evolutionary implications in a scenario governed by growth functions. The proposed growth functions, calibrated with data from the Crab pulsar, exhibit satisfactory physical behaviors. [ABSTRACT FROM AUTHOR]

Published

2024

15. Quantum refraction effects in pulsar emission.

Author

Kim, Dong-Hoon, Kim, Chul Min, and Kim, Sang Pyo

Subjects

*QUANTUM electrodynamics, *FARADAY effect, *NEUTRON stars, *REFRACTIVE index, *ELECTRODYNAMICS, *BIREFRINGENCE, *BINARY pulsars, *PULSARS

Abstract

Highly magnetized neutron stars exhibit the vacuum non-linear electrodynamics effects, which can be well-described using the one-loop effective action for quantum electrodynamics. In this context, we study the propagation and polarization of pulsar radiation, based on the post-Maxwellian Lagrangian from the Heisenberg–Euler–Schwinger action. Given the refractive index obtained from this Lagrangian, we determine the leading-order corrections to both the propagation and polarization vectors due to quantum refraction via perturbation analysis. In addition, the effects on the orthogonality between the propagation and polarization vectors and the Faraday rotation angle, all due to quantum refraction are investigated. Furthermore, from the dual refractive index and the associated polarization modes, we discuss quantum birefringence, with the optical phenomenology analogous to its classical counterpart. [ABSTRACT FROM AUTHOR]

Published

2024

16. A targeted radio pulsar survey of redback candidates with MeerKAT.

Author

Thongmeearkom, T, Clark, C J, Breton, R P, Burgay, M, Nieder, L, Freire, P C C, Barr, E D, Stappers, B W, Ransom, S M, Buchner, S, Calore, F, Champion, D J, Cognard, I, Grießmeier, J -M, Kramer, M, Levin, L, Padmanabh, P V, Possenti, A, Ridolfi, A, and Krishnan, V Venkatraman

Subjects

*STELLAR mass, *MEERKAT, *NEUTRON stars, *BINARY pulsars, *RADIO technology, *SPIDERS, PULSAR detection

Abstract

Redbacks are millisecond pulsar binaries with low-mass, irradiated companions. These systems have a rich phenomenology that can be used to probe binary evolution models, pulsar wind physics, and the neutron star mass distribution. A number of high-confidence redback candidates have been identified through searches for variable optical and X-ray sources within the localization regions of unidentified but pulsar-like Fermi -LAT gamma-ray sources. However, these candidates remain unconfirmed until pulsations are detected. As part of the TRAPUM project, we searched for radio pulsations from six of these redback candidates with MeerKAT. We discovered three new radio millisecond pulsars, PSRs J0838−2827, J0955−3947, and J2333−5526, confirming their redback nature. PSR J0838−2827 remained undetected for 2 yr after our discovery despite repeated observations, likely due to evaporated material absorbing the radio emission for long periods of time. While, to our knowledge, this system has not undergone a transition to an accreting state, the disappearance, likely caused by extreme eclipses, illustrates the transient nature of spider pulsars and the heavy selection bias in uncovering their radio population. Radio timing enabled the detection of gamma-ray pulsations from all three pulsars, from which we obtained 15-yr timing solutions. All of these sources exhibit complex orbital period variations consistent with gravitational quadrupole moment variations in the companion stars. These timing solutions also constrain the binary mass ratios, allowing us to narrow down the pulsar masses. We find that PSR J2333−5526 may have a neutron star mass in excess of 2 M⊙. [ABSTRACT FROM AUTHOR]

Published

2024

17. The effect of pulsar geometry on the observed gamma-ray spectrum of millisecond pulsars.

Author

Lloyd, Sheridan J, Chadwick, Paula M, and Brown, Anthony M

Subjects

*PULSARS, *GLOBULAR clusters, *GEOMETRY, *MAGNETIC fields, *GAMMA ray astronomy, *BINARY pulsars, *PARABOLA

Abstract

We analyse 13 yr of Fermi Large Area Telescope Pass 8 events from 127 gamma-ray emitting millisecond pulsars (MSPs) in the energy range 0.1–100 GeV and significantly detect 118 MSPs. We fit the stacked emission with a log parabola (LP) spectral model that we show is preferred to two previously published models. We consider the influence of pulsar properties and observed geometric effects on spectral features by defining energy flux colours for both the individual MSPs, and our stacked model as a baseline. There is no correlation of colours with pulsar luminosity, |$\dot{E}$|⁠ , surface magnetic field, or magnetic impact angle. We also find that pulsar geometry has little effect on the observed gamma-ray spectrum, which is in tension with previous modelling of gamma-ray emission with respect to pulsar geometry. Our LP MSP model is applicable to problems where an ensemble of gamma-ray MSPs is considered, such as that of the Galactic Centre excess or in the case of emission from globular clusters. [ABSTRACT FROM AUTHOR]

Published

2024

18. The impact of different magnetic braking prescriptions on the evolution of LMXBs.

Author

Echeveste, M, Novarino, M L, Benvenuto, O G, and De Vito, M A

Subjects

*BINARY pulsars, *X-ray binaries, *MEDICAL prescriptions, *MASS transfer, *ANGULAR momentum (Mechanics), *NEUTRON stars

Abstract

We revisit the evolution of low-mass close binary systems under different magnetic braking (MB) prescriptions. We study binaries with a neutron star accretor. During mass transfer episodes, these systems emit X-rays and are known as Low-mass X-ray Binaries (LMXBs). When mass transfer stops, they can be observed as binary pulsars. Additionally, some of these systems can experience mass transfer while having orbital periods of less than 1 h, thus evolving into ultracompact X-ray binaries (UCXBs). The evolution of LMXBs depends on their capability to lose angular momentum and maintain stable mass transfer. Among the angular momentum loss mechanisms, MB is one important and still uncertain phenomenon. The standard MB prescription faces some problems when calculating LMXB evolution, leading to e.g. a fine-tuning problem in the formation of UCXBs. Recent studies proposed new MB prescriptions, yielding diverse outcomes. Here, we investigate the effects of three novel MB prescriptions on the evolution of LMXBs using our stellar code. We found that all MB prescriptions considered allow the formation of binaries with orbital periods spanning from less than 1 h to more than 10 of days. Remarkably, our results enable the occurrence of wide systems even for the MB law that causes the strongest angular momentum losses and very high mass transfer rates. We found that models computed with the strongest MB prescription reach the UCXB state starting from a wider initial orbital period interval. Finally, we discuss and compare our results with observations and previous studies performed on this topic. [ABSTRACT FROM AUTHOR]

Published

2024

19. Electron-capture supernovae in NS + He star systems and the double neutron star systems.

Author

Guo, Yun-Lang, Wang, Bo, Chen, Wen-Cong, Li, Xiang-Dong, Ge, Hong-Wei, Jiang, Long, and Han, Zhan-Wen

Subjects

*NEUTRON stars, *BINARY stars, *SUPERNOVAE, *GRAVITATIONAL collapse, *STELLAR mass, *BINARY pulsars

Abstract

Electron-capture-supernovae (EC-SNe) provide an alternative channel for producing neutron stars (NSs). They play an important role in the formation of double NS (DNS) systems and the chemical evolution of galaxies, and contribute to the NS mass distribution in observations. It is generally believed that EC-SNe originate from e -captures on |$\rm ^{24}Mg$| and |$\rm ^{20}Ne$| in the massive degenerate oxygen–neon (ONe) cores with masses close to the Chandrasekhar limit (M Ch). However, the origin of EC-SNe is still uncertain. In this paper, we systematically studied the EC-SNe in NS + He star systems by considering the explosive oxygen burning that may occur in the near- M Ch ONe core. We provided the initial parameter spaces for producing EC-SNe in the initial orbital period − initial He star mass (log |$P_{\rm orb}^{\rm i}-M_{\rm He}^{\rm i}$|⁠) diagram, and found that both |$M_{\rm He}^{\rm i}$| and minimum |$P_{\rm orb}^{\rm i}$| for EC-SNe increase with metallicity. Then, by considering NS kicks added to the newborn NS, we investigated the properties of the formed DNS systems after the He star companions collapse into NSs, such as the orbital periods, eccentricities, and spin periods of recycle pulsars (P spin), etc. The results show that most of the observed DNS systems can be produced by NS kicks of |$\lesssim$| 50 km s−1. In addition, we found that NSs could accrete more material if the residual H envelope on the He star companions is considered, which can form the mildly recycled pulsars (P spin ∼ 20 ms) in DNS systems. [ABSTRACT FROM AUTHOR]

Published

2024

20. Spin period evolution of Vela pulsar based on the wind emission: Application to the long period radio pulsars GPM J1839‐10 (P = 21 min) and GLEAM‐X J1627 (P = 18 min).

Author

Sun, Yi‐Hong, Wang, De‐Hua, Zhang, Cheng‐Min, Cui, Xiang‐Han, Zhang, Jian‐Wei, Yu, Jing, Zhou, Yun‐Gang, and You, Zi‐Yi

Subjects

*PULSARS, *NEUTRON stars, *MAGNETIC dipoles, *BINARY pulsars, *ASTRONOMERS, *SUPERNOVA remnants

Abstract

The Vela pulsar is a young neutron star with spin period of P = 89 ms and a measured low braking index (˜1.4) that is much less than the standard value of 3 predicted by the magnetic dipole radiation (MDR) model; however, its spin period evolution has been a mystery. In this article, we assume that the spin‐down of the Vela pulsar is attributed to both MDR and wind flow (hereafter MDRW), and find that the ratio of wind flow to the magnetic dipole radiation is about 80%, which is higher than that of the Crab pulsar (25%). In other words, the spin‐down torque of the Vela pulsar is dominated by the wind flow. The spin period (P) evolution of the Vela pulsar depends on its real age, where its supernova remnant age is assumed to be an indicator of its true age, estimated from 10 to 20 kyr, and then we obtain their initial spin periods of ˜53.89 and ˜20.90 ms, respectively, which are consistent with the observed initial spin period ranges of young pulsars. Furthermore, we find that the Vela‐like pulsar by MDRW can evolve to the long spin period of a thousand of seconds in less than million years, which can conveniently help the astronomers understand the recently observed ultra‐long period radio pulsars like GPM J1839‐10 (P = 21 min), GLEAM‐X J1627 (P = 18 min), as well as PSR J0901+4046 (P = 76 s). [ABSTRACT FROM AUTHOR]

Published

2024

21. The Thousand-Pulsar-Array programme on MeerKAT – XIII. Timing, flux density, rotation measure, and dispersion measure time series of 597 pulsars.

Author

Keith, M J, Johnston, S, Karastergiou, A, Weltevrede, P, Lower, M E, Basu, A, Posselt, B, Oswald, L S, Parthasarathy, A, Cameron, A D, Serylak, M, and Buchner, S

Subjects

*ACTINIC flux, *TIME series analysis, *PULSARS, *MEERKAT, *ELECTRON density, *BINARY pulsars

Abstract

We report here on the timing of 597 pulsars over the last four years with the MeerKAT telescope. We provide times of arrival, pulsar ephemeris files, and per-epoch measurements of the flux density, dispersion measure (DM), and rotation measure (RM) for each pulsar. In addition, we use a Gaussian process to model the timing residuals to measure the spin frequency derivative at each epoch. We also report the detection of 11 glitches in nine individual pulsars. We find significant DM and RM variations in 87 and 76 pulsars, respectively. We find that the DM variations scale approximately linearly with DM, which is broadly in agreement with models of the ionized interstellar medium. The observed RM variations seem largely independent of DM, which may suggest that the RM variations are dominated by variations in the interstellar magnetic field on the line of sight, rather than varying electron density. We also find that normal pulsars have around 5 times greater amplitude of DM variability compared to millisecond pulsars, and surmise that this is due to the known difference in their velocity distributions. [ABSTRACT FROM AUTHOR]

Published

2024

22. The FAST Galactic Plane Pulsar Snapshot Survey – V. PSR J1901+0658 in a double neutron star system.

Author

Su, W Q, Han, J L, Yang, Z L, Wang, P F, Yuan, J P, Wang, C, Zhou, D J, Wang, T, Yan, Y, Jing, W C, Cai, N N, Xie, L, Xu, J, Wang, H G, Xu, R X, and You, X P

Subjects

*NEUTRON stars, *BINARY stars, *BINARY pulsars, *PULSARS, *ORBITS (Astronomy), PULSAR detection

Abstract

Double neutron star (DNS) systems offer excellent opportunities to test gravity theories. We report the timing results of PSR J1901+0658, the first pulsar discovered in the FAST Galactic Plane Pulsar Snapshot (GPPS) Survey. Based on timing observations by FAST over 5 yr, we obtain the phase-coherent timing solution and derive the precise measurements of its position, spin parameters, orbital parameters, and dispersion measure. It has a period of 75.7 ms, a period derivative of 2.169(6) × 10−19 s s−1, and a characteristic age of 5.5 Gyr. This pulsar is in an orbit with a period of 14.45 d and an eccentricity of 0.366. One post-Keplerian parameter, periastron advance, has been well-measured as being 0.00531(9) deg yr−1, from which the total mass of this system is derived to be 2.79(7) M⊙. The pulsar has the mass upper limit of 1.68 M⊙, so the lower limit for the companion mass is 1.11 M⊙. Because PSR J1901+0658 is a partially recycled pulsar in an eccentric binary orbit with such a large companion mass, it should be in a DNS system according to the evolution history of the binary system. [ABSTRACT FROM AUTHOR]

Published

2024

23. Discoveries and timing of pulsars in M62.

Author

Vleeschower, L, Corongiu, A, Stappers, B W, Freire, P C C, Ridolfi, A, Abbate, F, Ransom, S M, Possenti, A, Padmanabh, P V, Balakrishnan, V, Kramer, M, Venkatraman Krishnan, V, Zhang, L, Bailes, M, Barr, E D, Buchner, S, and Chen, W

Subjects

*PULSARS, *GRAVITATIONAL fields, *BINARY pulsars, *ACTINIC flux, *GLOBULAR clusters, *NEUTRON stars, *MEERKAT

Abstract

Using MeerKAT , we have discovered three new millisecond pulsars (MSPs) in the bulge globular cluster M62: M62H, M62I, and M62J. All three are in binary systems, which means all ten known pulsars in the cluster are in binaries. M62H has a planetary-mass companion with a median mass M c, med ∼ 3 MJ and a mean density of ρ ∼ 11 g cm−3. M62I has an orbital period of 0.51 d and a M c, med ∼ 0.15 M⊙. Neither of these low-mass systems exhibit eclipses. M62J has only been detected in the two Ultra High Frequency band (816 MHz) observations with a flux density S 816 = 0.08 mJy. The non-detection in the L-band (1284 MHz) indicates it has a relatively steep spectrum (β < −3.1). We also present 23-yr-long timing solutions obtained using data from the Parkes 'Murriyang', Effelsberg , and MeerKAT telescopes for the six previously known pulsars. For all these pulsars, we measured the second spin-period derivatives and the rate of change of orbital period caused by the gravitational field of the cluster, and their proper motions. From these measurements, we conclude that the pulsars' maximum accelerations are consistent with the maximum cluster acceleration assuming a core-collapsed mass distribution. Studies of the eclipses of the redback M62B and the black widow M62E at four and two different frequency bands, respectively, reveal a frequency dependence with longer and asymmetric eclipses at lower frequencies. The presence of only binary MSPs in this cluster challenges models which suggest that the MSP population of core-collapsed clusters should be dominated by isolated MSPs. [ABSTRACT FROM AUTHOR]

Published

2024

24. A 350 MHz Green Bank Telescope Survey of Unassociated Fermi LAT Sources: Discovery and Timing of 10 Millisecond Pulsars.

Author

Bangale, P., Bhattacharyya, B., Camilo, F., Clark, C. J., Cognard, I., DeCesar, M. E., Ferrara, E. C., Gentile, P., Guillemot, L., Hessels, J. W. T., Johnson, T. J., Kerr, M., McLaughlin, M. A., Nieder, L., Ransom, S. M., Ray, P. S., Roberts, M. S. E., Roy, J., Sanpa-arsa, S., and Theureau, G.

Subjects

*TELESCOPES, *BINARY pulsars

Abstract

We have searched for radio pulsations toward 49 Fermi Large Area Telescope (LAT) 1FGL Catalog γ -ray sources using the Green Bank Telescope at 350 MHz. We detected 18 millisecond pulsars (MSPs) in blind searches of the data; 10 of these were discoveries unique to our survey. 16 are binaries, with eight having short orbital periods P B < 1 day. No radio pulsations from young pulsars were detected, although three targets are coincident with apparently radio-quiet γ -ray pulsars discovered in LAT data. Here, we give an overview of the survey and present radio and γ -ray timing results for the 10 MSPs discovered. These include the only isolated MSP discovered in our survey and six short- P B binary MSPs. Of these, three have very-low-mass companions (M c ≪ 0.1 M ⊙) and hence belong to the class of black widow pulsars. Two have more massive, nondegenerate companions with extensive radio eclipses and orbitally modulated X-ray emission consistent with the redback class. Significant γ -ray pulsations have been detected from nine of the discoveries. This survey and similar efforts suggest that the majority of Galactic γ -ray sources at high Galactic latitudes are either MSPs or relatively nearby nonrecycled pulsars, with the latter having on average a much smaller radio/ γ -ray beaming ratio as compared to MSPs. It also confirms that past surveys suffered from an observational bias against finding short- P B MSP systems. [ABSTRACT FROM AUTHOR]

Published

2024

25. Probing the emission mechanism and nature of the pulsating compact object in the X-ray binary SAX J1324.4−6200.

Author

Ducci, L., Bozzo, E., Burgay, M., Malacaria, C., Ridolfi, A., Romano, P., Serim, M. M., Vercellone, S., and Santangelo, A.

Subjects

*X-ray binaries, *ACTIVE galactic nuclei, *X-ray spectra, *PULSATING stars, *MAGNETIC fields, *BINARY pulsars, *PULSARS

Abstract

Recently, there has been renewed interest in the Be X-ray binary (Be/XRB) SAX J1324.4−6200 because of its spatial coincidence with a variable γ-ray source detected by Fermi/LAT. To explore more thoroughly its properties, new X-ray observations were carried out in 2023 by NuSTAR, XMM-Newton, and Swift satellites, jointly covering the energy range from 0.2 − 79 keV. SAX J1324.4−6200 was caught at an X-ray flux of ∼10−11 erg cm−2 s−1. The X-ray spectrum fits well with an absorbed power law with a high energy cutoff. Other acceptable fits require an additional blackbody component (kTbb ≈ 1.1 keV) or a Gaussian in absorption (Egabs ≈ 6.9 keV). We measured a NuSTAR spin period of 175.8127 ± 0.0036 s and an XMM-Newton spin period of 175.862 ± 0.025 s. We show that all the available spin period measurements of SAX J1324.4−6200, spanning 29 yr, are highly correlated with time, resulting in a remarkably stable spin-down of Ṗ = 6.09 ± 0.06 × 10−9 s s−1. We find that if SAX J1324.4−6200 hosts an accretion-powered pulsar, accretion torque models indicate a surface magnetic field of ∼1012 − 13 G. The X-ray properties emerging from our analysis strenghten the hypothesis that SAX J1324.4−6200 belongs to the small group of persistent Be/XRBs. We also performed radio observations with the Parkes Murriyang telescope, to search for radio pulsations. However, no radio pulsations compatible with the rotational ephemeris of SAX J1324.4−6200 were detected. We rule out the hypothesis that SAX J1324.4−6200 is a γ-ray binary where the emission is produced by interactions between the pulsar and the companion winds. Other models commonly used to account for the production of γ-rays in accreting pulsars cannot reproduce the bright emission from SAX J1324.4−6200. We examined other possible mechanisms behind the γ-ray emission and note that there is a ∼0.5% chance probability that an unknown extragalactic active galactic nucleus (AGN) observed through the Galactic plane may coincidentally fall within the Fermi/LAT error circle of the source and be responsible for the γ-ray emission. [ABSTRACT FROM AUTHOR]

Published

2024

26. Magnetic-field oscillation model of pulsar radio emission: prediction of an observable effect.

Author

Liang, Zhu-Xing and Liang, Yi

Subjects

*MAIN sequence (Astronomy), *PULSARS, *NEUTRON stars, *CIRCULAR polarization, *STELLAR magnetic fields, *DWARF stars, *BINARY pulsars

Abstract

Since the discovery of pulsars, the rotating-lighthouse model has been the choice of model to explain the radiation pulsation of pulsars. After discovering that some main sequence stars (e.g. CU Virginis) and ultracool dwarfs (e.g. TVLM 513−46546) also behave like pulsars, the lighthouse model was again adopted to explain their pulse signals. Our research found that if we use the magnetic-field oscillation (MO) model, we can explain the pulse radiation results better regardless of whether its source is a neutron star, a main-sequence star, or an ultracool dwarf. We propose a verifiable prediction that can be used to evaluate the MO model. Our prediction is that there is a 90° phase lag between the magnetic field and radio signal of TVLM 513−46546, and the zero-crossing point of the magnetic field is the moment when the direction of the light's circular polarization is reversed. No new observations are needed to check this prediction, but certain existing data needs to be re-mined. [ABSTRACT FROM AUTHOR]

Published

2024

27. Measuring a Gravitomagnetic Effect with the Triple Pulsar PSR J0337+1715.

Author

Iorio, Lorenzo

Subjects

*PULSARS, *ANGULAR momentum (Mechanics), *BINARY pulsars, *GRAVITATIONAL potential, *MULTIPLE stars, *ORBITS (Astronomy), *BINARY black holes

Abstract

To the first post-Newtonian order, the orbital angular momentum of the fast-revolving inner binary of the triple system PSR J0337+1715, made of a millisecond pulsar and a white dwarf, induces an annular gravitomagnetic field which displaces the line of apsides of the slower orbit of the other, distant white dwarf by − 1.2 milliarcseconds per year. The current accuracy in determining the periastron of the outer orbit is 63.9 milliarcseconds after 1.38 years of data collection. By hypothesizing a constant rate of measurement of the pulsar's times of arrivals over the next 10 years, assumed equal to the present one, it can be argued that the periastron will be finally known to a ≃ 0.15 milliarcseconds level, while its cumulative gravitomagnetic retrograde shift will be as large as − 12 milliarcseconds. The competing post-Newtonian gravitolectric periastron advance due to the inner binary's masses, nominally amounting to 74.3 milliarcseconds per year, can be presently modelled to an accuracy level as good as ≃ 0.04 milliarcseconds per year. The mismodeling in the much larger Newtonian periastron rate due to the quadrupolar term of the multipolar expansion of the gravitational potential of a massive ring representing the inner binary, whose nominal size for PSR J0337+1715 is 0.17 degrees per year, might be reduced down to the ≃ 0.5 milliarcseconds per year level over the next 10 years. Thus, a first measurement of such a novel form of gravitomagnetism, although undoubtedly challenging, might be, perhaps, feasible in a not too distant future. [ABSTRACT FROM AUTHOR]

Published

2024

28. Pulsed Iron Line Emission from the First Galactic Ultraluminous X-Ray Pulsar Swift J0243.6+6124.

Author

Xiao, Y. X., Xu, Y. J., Ge, M. Y., Lu, F. J., Zhang, S. N., Zhang, S., Tao, L., Qu, J. L., Wang, P. J., Kong, L. D., Tuo, Y. L., You, Y., Zhao, S. J., Peng, J. Q., Du, Y. F., Zhang, Y. H., and Ye, W. T.

Subjects

*X-ray telescopes, *IRON, *X-ray binaries, *PULSARS, *HARD X-rays, *X-rays

Abstract

We report the phase-resolved spectral results of the first Galactic pulsating ultraluminous X-ray source (PULX) Swift J0243.6+6124, modeling its 2017–2018 outburst peak using data collected by the Hard X-ray Modulation Telescope (Insight-HXMT). The broad energy coverage of Insight-HXMT allows us to obtain a more accurate spectral continuum to reduce the coupling of broad iron line profiles with other components. We use three different continuum spectrum models but obtain similar iron line results. For the first time, we detect the pulse characteristics of the broad iron line in a PULX. The variation in the width and intensity of this iron line with σ ∼ 1.2–1.5 keV has a phase offset of about 0.25 from the pulse phase. We suggest that the uneven irradiation of the thick inner disk by the accretion column produces the modulated variation of the broad iron line. In addition, the nonpulsed narrow line is suggested to come from the outer disk region. [ABSTRACT FROM AUTHOR]

Published

2024

29. Broad-band noise and quasi-periodic oscillation characteristics of the X-ray pulsar RX J0440.9+4431.

Author

Li, P P, Tao, L, Ma, R C, Ge, M Y, Zhao, Q C, Zhao, S J, Zhang, L, Bu, Q C, Kong, L D, Tuo, Y L, Ji, L, Zhang, S, Qu, J L, Zhang, S N, Huang, Y, Ma, X, Ye, W T, and Shui, Q C

Subjects

*BINARY pulsars, *PULSARS, *X-rays, *POWER spectra, *LIGHT curves, *ACCRETION (Astrophysics), *SOLAR flares, *GAMMA ray bursts

Abstract

We present a comprehensive timing analysis on the Be/X-ray binary pulsar RX J0440.9+4431 using observations from NICER and Insight - HXMT during the 2022–2023 outburst. The power density spectrum (PDS) of RX J0440.9+4431 exhibits typical aperiodic variability in X-ray flux across a wide frequency range. During a supercritical accretion state, we detect quasi-periodic oscillations (QPOs) at 0.2–0.5 Hz in the light curves of five pulses for RX J0440.9+4431. The observed QPOs manifest during flares, while the flares appear at the peaks of the pulse profiles on a time-scale of seconds and are primarily caused by an increase in hard photons. These flares can be explained by increased material ingestion in the accretion column at a fixed phase, primarily generating hard photons. Alternatively, an increase in accretion rate, independent of phase, may result in highly beamed hard photons within the accretion column, causing the flares. We argue the origin of QPOs to instabilities within the accretion flow. Additionally, we find that the break frequencies in the noise power spectra align well with |$\propto L_{\mathrm{x}}^{3 / 7}$| across three orders of magnitude in the luminosity, which points to a relatively strong magnetic field in RX J0440.9+4431, estimated to be ~1013 G. [ABSTRACT FROM AUTHOR]

Published

2024

30. Measuring the Lense–Thirring Orbital Precession and the Neutron Star Moment of Inertia with Pulsars.

Author

Hu, Huanchen and Freire, Paulo C. C.

Subjects

*NEUTRON stars, *MOMENTS of inertia, *PULSARS, *BINARY pulsars, *STELLAR evolution, *BINARY stars

Abstract

Neutron stars (NSs) are compact objects that host the densest forms of matter in the observable universe, providing unique opportunities to study the behaviour of matter at extreme densities. While precision measurements of NS masses through pulsar timing have imposed effective constraints on the equation of state (EoS) of dense matter, accurately determining the radius or moment of inertia (MoI) of an NS remains a major challenge. This article presents a detailed review on measuring the Lense–Thirring (LT) precession effect in the orbit of binary pulsars, which would give access to the MoI of NSs and offer further constraints on the EoS. We discuss the suitability of certain classes of binary pulsars for measuring the LT precession from the perspective of binary star evolution and highlight five pulsars that exhibit properties promising to realise these goals in the near future. Finally, discoveries of compact binaries with shorter orbital periods hold the potential to greatly enhance measurements of the MoI of NSs. The MoI measurements of binary pulsars are pivotal to advancing our understanding of matter at supranuclear densities, as well as improving the precision of gravity tests, such as the orbital decay due to gravitational wave emission, and of tests of alternative gravity theories. [ABSTRACT FROM AUTHOR]

Published

2024

31. Modeling X-Ray and Gamma-Ray Emission from Redback Pulsar Binaries.

Author

Sim, Minju, An, Hongjun, and Wadiasingh, Zorawar

Subjects

*BINARY pulsars, *PARTICLE acceleration, *SYNCHROTRON radiation, *SPECTRAL energy distribution, *LOW mass stars, *GAMMA ray bursts

Abstract

We investigated the multiband emission from the pulsar binaries XSS J12270−4859, PSR J2039−5617, and PSR J2339−0533, which exhibit orbital modulation in the X-ray and gamma-ray bands. We constructed the sources' broadband spectral energy distributions and multiband orbital light curves by supplementing our X-ray measurements with published gamma-ray results, and we modeled the data using intrabinary shock (IBS) scenarios. While the X-ray data were well explained by synchrotron emission from electrons/positrons in the IBS, the gamma-ray data were difficult to explain with the IBS components alone. Therefore, we explored other scenarios that had been suggested for gamma-ray emission from pulsar binaries: (1) inverse-Compton emission in the upstream unshocked wind zone and (2) synchrotron radiation from electrons/positrons interacting with the kilogauss magnetic field of the companion. Scenario (1) requires that the bulk motion of the wind substantially decelerates to ∼1000 km s−1 before reaching the IBS for increased residence time, in which case the formation of a strong shock is untenable, inconsistent with the X-ray phenomenology. Scenario (2) can explain the data if we assume the presence of electrons/positrons with a Lorentz factor ∼ 108 (∼0.1 PeV) that pass through the IBS and tap a substantial portion of the pulsar voltage drop. These findings raise the possibility that the orbitally modulating gamma-ray signals from pulsar binaries can provide insights into the flow structure and energy conversion within pulsar winds and particle acceleration nearing PeV energies in pulsars. These signals may also yield greater understanding of kilogauss magnetic fields potentially hosted by the low-mass stars in these systems. [ABSTRACT FROM AUTHOR]

Published

2024

32. The invisible black widow PSR J1720−0534: implications for the electron density towards the North Polar Spur.

Author

Koljonen, K I I, Lindseth, S S, Linares, M, Harding, A K, and Turchetta, M

Subjects

*ELECTRON density, *BINARY pulsars, *OPTICAL telescopes, *PARALLAX, *INTERSTELLAR medium

Abstract

Radio emission from pulsars can be used to map out their distances through dispersion measure (DM), which quantifies the amount of radio pulse dispersion. However, this method relies on accurately modelling the free electron density in the line of sight. Here, we present a detailed study of the multiwavelength emission from PSR J1720−0534, a black widow compact binary millisecond pulsar discovered in 2021, which the latest electron density model of the Galaxy places at only 191 pc. We obtained and analysed deep multiwavelength observations in the γ-ray (Fermi -Large Area Telescope, 2008–2022), optical (Las Cumbres Observatory, 2.7 h), near-infrared (Nordic Optical Telescope, 3.5 h), and X-ray (Swift -X-Ray Telescope, 10 ks) bands. We found no significant detection of γ-ray, optical, near-infrared, or X-ray counterparts around the radio-timing position of PSR J1720−0534, which we thus nickname 'the invisible black widow'. Employing the most constraining near-infrared limit (J > 23.4 mag), we established a lower limit on the source distance, d > 1.1 kpc, assuming conservative properties for the black widow companion star. This distance lower limit differs drastically (by a factor of more than 5) from the Yao et al. DM distance estimate. We attribute this difference to the inclusion in the Yao et al. model of a large and dense component towards the North Polar Spur. Considering our results and recent parallax distances to other pulsars in this direction, we argue that such a local and large component in the electron density model of the Galaxy is unnecessary. [ABSTRACT FROM AUTHOR]

Published

2024

33. Cyclotron line evolution revealed with pulse-to-pulse analysis in the 2020 outburst of 1A 0535+262.

Author

Shui, Qing C, Zhang, S, Wang, Peng J, Mushtukov, Alexander A, Santangelo, A, Zhang, Shuang N, Kong, Ling D, Ji, L, Chen, Yu P, Doroshenko, V, Frontera, F, Chang, Z, Peng, Jing Q, Yin, Hong X, Qu, Jin L, Tao, L, Ge, Ming Y, Li, J, Ye, Wen T, and Li, Pan P

Subjects

*BINARY pulsars, *X-ray telescopes, *HARD X-rays, *CYCLOTRONS, *NEUTRON stars, *X-ray binaries

Abstract

We present a detailed analysis of the X-ray luminosity (L X) dependence of the cyclotron absorption line energy (E cyc) for the X-ray binary pulsar 1A 0535+262 during its 2020 giant outburst based on pulse-to-pulse analysis. By applying this technique to high cadence observations of Insight - Hard X-ray Modulation Telescope , we reveal the most comprehensive E cyc– L X correlation across a broad luminosity range of ∼(0.03–1.3) × 1038 erg s−1. Apart from the positive and negative correlations between cyclotron line energy and luminosity at L X ∼ (1–3) × 1037 erg s−1 and ∼(7–13) × 1037 erg s−1, which are expected from the typical subcritical and supercritical accretion regimes, respectively, a plateau in the correlation is also detected at ∼(3–7) × 1037 erg s−1. Moreover, at the lowest luminosity level (L X ≲ 1037 erg s−1), the positive E cyc –L X correlation seems to be broken, and the pulse profile also occurs a significant transition. These discoveries provide the first complete view on the correlation between luminosity and the centriod energy of the cyclotron line, and therefore are relevant for understanding how accretion on to magnetized neutron stars depends on luminosity. [ABSTRACT FROM AUTHOR]

Published

2024

34. Discovery of radio eclipses from 4FGL J1646.5−4406: a new candidate redback pulsar binary.

Author

Zic, Andrew, Wang, Ziteng, Lenc, Emil, Kaplan, David L, Murphy, Tara, Ridolfi, A, Sengar, Rahul, Hurley-Walker, Natasha, Dobie, Dougal, Leung, James K, Pritchard, Joshua, and Wang, Yuanming

Subjects

*INTERSTELLAR medium, *LOW mass stars, *VARIABLE stars, *BINARY pulsars, *RADIO telescopes, *ECLIPSING binaries, *PULSARS

Abstract

Large widefield surveys make possible the serendipitous discovery of rare subclasses of pulsars. One such class are 'spider'-type pulsar binaries, comprised of a pulsar in a compact orbit with a low-mass (sub)stellar companion. In a search for circularly polarized radio sources in Australian Square Kilometre Array Pathfinder (ASKAP) Pilot Survey observations, we discovered highly variable and circularly polarized emission from a radio source within the error region of the γ-ray source 4FGL J1646.5−4406. The variability is consistent with the eclipse of a compact, steep-spectrum source behind ablated material from a companion in an ∼5.3 h binary orbit. Based on the eclipse properties and spatial coincidence with 4FGL J1646.5−4406, we argue that the source is likely a recycled pulsar in a 'redback' binary system. Using properties of the eclipses from ASKAP and Murchison Widefield Array observations, we provide broad constraints on the properties of the eclipse medium. We identified a potential optical/infrared counterpart in archival data consistent with a variable low-mass star. Using the Parkes radio telescope 'Murriyang' and the Meer Karoo Array Telescope (MeerKAT) , we searched extensively for radio pulsations but yielded no viable detections of pulsed emission. We suggest that the non-detection of pulses is due to scattering in the intra-binary material, but scattering from the interstellar medium can also plausibly explain the pulse non-detections if the interstellar dispersion measure exceeds ∼600 pc cm−3. Orbital constraints derived from optical observations of the counterpart would be highly valuable for future γ-ray pulsation searches, which may confirm the source nature as a pulsar. [ABSTRACT FROM AUTHOR]

Published

2024

35. Mass estimates from optical modelling of the new TRAPUM redback PSR J1910−5320.

Author

Dodge, O G, Breton, R P, Clark, C J, Burgay, M, Strader, J, Au, K -Y, Barr, E D, Buchner, S, Dhillon, V S, Ferrara, E C, Freire, P C C, Griessmeier, J -M, Kennedy, M R, Kramer, M, Li, K -L, Padmanabh, P V, Phosrisom, A, Stappers, B W, Swihart, S J, and Thongmeearkom, T

Subjects

*NEUTRON stars, *STELLAR mass, *LIGHT curves, *TECHNOLOGICAL innovations, *PULSARS, *BINARY pulsars, *GAMMA ray astronomy, *COINCIDENCE

Abstract

Spider pulsars continue to provide promising candidates for neutron star mass measurements. Here we present the discovery of PSR J1910−5320, a new millisecond pulsar discovered in a MeerKAT observation of an unidentified Fermi -LAT gamma-ray source. This pulsar is coincident with a recently identified candidate redback binary, independently discovered through its periodic optical flux and radial velocity. New multicolour optical light curves obtained with ULTRACAM/New Technology Telescope in combination with MeerKAT timing and updated SOAR/Goodman spectroscopic radial velocity measurements allow a mass constraint for PSR J1910−5320. icarus optical light curve modelling, with streamlined radial velocity fitting, constrains the orbital inclination and companion velocity, unlocking the binary mass function given the precise radio ephemeris. Our modelling aims to unite the photometric and spectroscopic measurements available by fitting each simultaneously to the same underlying physical model, ensuring self-consistency. This targets centre-of-light radial velocity corrections necessitated by the irradiation endemic to spider systems. Depending on the gravity darkening prescription used, we find a moderate neutron star mass of either 1.6 ± 0.2 or 1.4 ± 0.2 M ⊙. The companion mass of either 0.45 ± 0.04 or |$0.43^{+0.04}_{-0.03}$| M ⊙ also further confirms PSR J1910−5320 as an irradiated redback spider pulsar. [ABSTRACT FROM AUTHOR]

Published

2024

36. Estimation of Pulsar's Initial Spin by the Magnetic Dipole Radiation and Wind Model.

Author

Yihong Sun, Wang, Dehua, Zhang, Chengmin, Yu, Jing, Zhou, Yungang, You, Ziyi, Cui, Xianghan, and Zhang, Jianwei

Subjects

*MAGNETIC dipoles, *STELLAR evolution, *SUPERGIANT stars, *RADIATION, *BINARY pulsars

Abstract

The estimation of the initial spin period of pulsars involves the important questions such as the late stage evolution of massive stars and the formation process of neutron stars. However, the estimated initial spin exists the bias based on the magnetic dipole radiation (MDR) model, since the braking index of a dozen of observed pulsars ranges in that is deviated from the expected value of 3 by MDR. The magnetic dipole radiation plus wind (MDRW) model for a pulsar successfully explains the evolution of the braking index between 1 and 3, by which we calculate the initial spins of the pulsars with the measured braking index, and obtain their distribution between and ms. This result is consistent with the statistics of the observed young pulsars, less than the fastest spin period of 16 ms of the rotation-powered X-ray pulsar PSR J0537–6910. [ABSTRACT FROM AUTHOR]

Published

2024

37. First Systematic Study Reporting the Changes in Eclipse Cutoff Frequency for Pulsar J1544+4937.

Author

Kumari, Sangita, Bhattacharyya, Bhaswati, Sharan, Rahul, Kansabanik, Devojyoti, Stappers, Benjamin, and Roy, Jayanta

Subjects

*PULSARS, *ELECTRON density, *RADIO telescopes, *ECLIPSES, *BINARY pulsars, *ORBITS (Astronomy)

Abstract

We present results from long-term monitoring of frequency-dependent eclipses of the radio emission from PSR J1544+4937, which is a black widow spider millisecond pulsar (MSP) in a compact binary system. The majority of such systems often exhibit relatively long-duration radio eclipses caused by ablated material from their companion stars. With the wide spectral bandwidth of the upgraded Giant Metrewave Radio Telescope, we present the first systematic study of temporal variation of eclipse cutoff frequency. With decade-long monitoring of 39 eclipses for PSR J1544+4937, we notice significant changes in the observed cutoff frequency ranging from 343 ± 7 to ≥740 MHz. We also monitored changes in eclipse cutoff frequency on timescales of tens of days and observed a maximum change of ≥315 MHz between observations that were separated by 22 days. In addition, we observed a change of ∼47 MHz in eclipse cutoff frequency between adjacent orbits, i.e., on timescales of ∼2.9 hr. We infer that such changes in the eclipse cutoff frequency depict an eclipse environment for the PSR J1544+4937 system that is dynamically evolving, where, along with the change in electron density, the magnetic field could also be varying. We also report a significant correlation between the eclipse cutoff frequency and the mass-loss rate of the companion. This study provides the first direct evidence of mass-loss rate affecting the frequency-dependent eclipsing in a spider MSP. [ABSTRACT FROM AUTHOR]

Published

2024

38. PSR J0210+5845: Ultra-wide binary pulsar with a B6 V main sequence star companion.

Author

van der Wateren, E., Bassa, C. G., Janssen, G. H., Yanes-Rizo, I. V., Casares, J., Nelemans, G., Stappers, B. W., and Tan, C. M.

Subjects

*MAIN sequence (Astronomy), *BINARY pulsars, *STELLAR evolution, *OPTICAL spectroscopy, *SUPERNOVAE

Abstract

We report on radio timing observations of PSR J0210+5845 that reveal large deviations from typical pulsar spin-down behaviour. We interpret these deviations as being due to the binary motion around the V = 13.5 star 2MASS J02105640+5845176, which is coincident in terms of its celestial position and distance with the pulsar. Archival observations and new optical spectroscopy have identified this object as a B6 V star, with a temperature of Teff ≈ 14 000 K and a mass of Mc = 3.5 to 3.8 M⊙, making it the lowest mass for a main sequence star known to be orbiting a non-recycled pulsar. We find that the timing observations constrain the binary orbit to be wide and moderately eccentric, with an orbital period of Pb = 47−14+40 yr and eccentricity of e = 0.46−0.07+0.10. We predict that the next periastron passage will occur between 2030 and 2034. Due to the low companion mass, we find that the probability for a system with the properties of PSR J0210+5845 and its binary companion to survive the supernova is low. We show that a low velocity and fortuitously directed natal kick is required for the binary to remain bound during the supernova explosion and we argue that an electron-capture supernova is a plausible formation scenario for the pulsar. [ABSTRACT FROM AUTHOR]

Published

2024

39. Detection of the relativistic Shapiro delay in a highly inclined millisecond pulsar binary PSR J1012−4235.

Author

Gautam, T., Freire, P. C. C., Wu, J., Venkatraman Krishnan, V., Kramer, M., Barr, E. D., Bailes, M., and Cameron, A. D.

Subjects

*BINARY pulsars, *MOTION capture (Human mechanics), *RADIO telescopes, *GENERAL relativity (Physics), *SPACE telescopes

Abstract

PSR J1012−4235 is a 3.1 ms pulsar in a wide binary (37.9 days) with a white dwarf companion. We detect, for the first time, a strong relativistic Shapiro delay signature in PSR J1012−4235. Our detection is the result of a timing analysis of data spanning 13 yr and collected with the Green Bank, Parkes, and MeerKAT Radio Telescopes and the Fermiγ-ray space telescope. We measured the orthometric parameters for Shapiro delay and obtained a 22σ detection of the h3 parameter of 1.222(54) μs and a 200σ detection of ς of 0.9646(49). With the assumption of general relativity, these measurements constrain the pulsar mass (Mp = 1.44−0.12+0.13 M⊙), the mass of the white dwarf companion (Mc = 0.270−0.015+0.016M⊙), and the orbital inclination (i = 88.06−0.25+0.28 deg). Including the early γ-ray data in our timing analysis facilitated a precise measurement of the proper motion of the system of 6.58(5) mas yr−1. We also show that the system has unusually small kinematic corrections to the measurement of the orbital period derivative, and therefore has the potential to yield stringent constraints on the variation of the gravitational constant in the future. [ABSTRACT FROM AUTHOR]

Published

2024

40. A pulsar in a binary with a compact object in the mass gap between neutron stars and black holes.

Author

Barr, Ewan D., Dutta, Arunima, Freire, Paulo C. C., Cadelano, Mario, Gautam, Tasha, Kramer, Michael, Pallanca, Cristina, Ransom, Scott M., Ridolfi, Alessandro, Stappers, Benjamin W., Tauris, Thomas M., Krishnan, Vivek Venkatraman, Wex, Norbert, Bailes, Matthew, Behrend, Jan, Buchner, Sarah, Burgay, Marta, Weiwei Chen, Champion, David J., and Chen, C.-H. Rosie

Subjects

*BLACK holes, *NEUTRON stars, *BINARY pulsars, *GLOBULAR clusters, *GRAVITATIONAL waves, *PULSARS

Abstract

Some compact objects observed in gravitational wave events have masses in the gap between known neutron stars (NSs) and black holes (BHs). The nature of these mass gap objects is unknown, as is the formation of their host binary systems. We report pulsar timing observations made with the Karoo Array Telescope (MeerKAT) of PSR J0514−4002E, an eccentric binary millisecond pulsar in the globular cluster NGC 1851. We found a total binary mass of 3.887 ± 0.004 solar masses (M⊙), and multiwavelength observations show that the pulsar’s binary companion is also a compact object. The companion’s mass (2.09 to 2.71 M⊙, 95% confidence interval) is in the mass gap, indicating either a very massive NS or a low-mass BH. We propose that the companion formed in a merger between two earlier NSs. [ABSTRACT FROM AUTHOR]

Published

2024

41. Studying the variability of fluorescence emission and the presence of clumpy wind in HMXB GX 301−2 using XMM–Newton.

Author

Roy, Kinjal, Manikantan, Hemanth, and Paul, Biswajit

Subjects

*X-ray binaries, *NEUTRON stars, *BINARY pulsars, *STELLAR winds, *IRON, *FLUORESCENCE

Abstract

We present the results from an analysis of data from an XMM–Newton observation of the accreting high-mass X-ray binary pulsar GX 301−2. Spectral analysis in the non-flaring segment of the observation revealed that the equivalent width of the iron fluorescence emission is correlated with the observed absorption column density and the ratio of the iron Kβ and Kα line strength varied with the flux of the source. Coherent pulsations were detected with the spin period of the pulsar of 687.9 ± 0.1 s, and a secondary pulsation was also detected with a period of 671.8 ± 0.2 s, most prominent in the energy band of the iron line. At the spin period of the neutron star, the pulsation of the iron line has a low amplitude and the profile is different from the continuum. Pulse phase-resolved spectroscopy also revealed pulsations of the iron emission line during the non-flaring segment of the light curve. At the secondary period, both the iron line and the continuum have nearly identical pulse fraction and pulse profile. The additional periodicity can be attributed to the beat frequency between the spin of the neutron star and the Keplerian frequency of a stellar wind clump in retrograde motion around the neutron star. Reprocessed X-ray emissions originating from the clump can produce the observed secondary pulsations both in the continuum and the iron fluorescence line. The clump rotating around the neutron star is estimated to be approximately five lt-s away from the neutron star. [ABSTRACT FROM AUTHOR]

Published

2024

42. The High Time Resolution Universe Pulsar survey – XVIII. The reprocessing of the HTRU-S Low Lat survey around the Galactic Centre using a Fast Folding Algorithm pipeline for accelerated pulsars.

Author

Wongphechauxsorn, J, Champion, D J, Bailes, M, Balakrishnan, V, Barr, E D, Bernadich, M C i, Bhat, N D R, Burgay, M, Cameron, A D, Chen, W, Flynn, C M L, Jameson, A, Johnston, S, Keith, M J, Kramer, M, Ng, C, Possenti, A, Sengar, R, Shannon, R M, and Stappers, B

Subjects

*MAGNETIC flux density, *FAST Fourier transforms, *BINARY pulsars, *LINEAR polarization, *PULSARS, PULSAR detection, UNIVERSE

Abstract

The HTRU-S Low Latitude survey data within 1° of the Galactic Centre (GC) were searched for pulsars using the Fast Folding Algorithm (FFA). Unlike traditional Fast Fourier Transform (FFT) pipelines, the FFA optimally folds the data for all possible periods over a given range, which is particularly advantageous for pulsars with low-duty cycles. For the first time, a search over acceleration was included in the FFA to improve its sensitivity to binary pulsars. The steps in dispersion measure (DM) and acceleration were optimized, resulting in a reduction of the number of trials by 86 per cent. This was achieved over a search period range from 0.6 to 432-s, i.e. 10 per cent of the observation time (4320s), with a maximum DM of 4000 pc cm−3 and an acceleration range of ±128 m s−2. The search resulted in the re-detections of four known pulsars, including a pulsar that was missed in the previous FFT processing of this survey. This result indicates that the FFA pipeline is more sensitive than the FFT pipeline used in the previous processing of the survey within our parameter range. Additionally, we discovered a 1.89-s pulsar, PSR J1746-2829, with a large DM, located 0.5 from the GC. Follow-up observations revealed that this pulsar has a relatively flat spectrum (α = −0.9 ± 0.1) and has a period derivative of ∼1.3 × 10−12 s s−1, implying a surface magnetic field of ∼5.2 × 1013 G and a characteristic age of ∼23 000 yr. While the period, spectral index, and surface magnetic field strength are similar to many radio magnetars, other characteristics such as high linear polarization are absent. [ABSTRACT FROM AUTHOR]

Published

2024

43. Polarization of Intrabinary Shock Emission in Spider Pulsars.

Author

Sullivan, Andrew G. and Romani, Roger W.

Subjects

*SYNCHROTRON radiation, *MAGNETIC structure, *MAGNETIC fields, *BREWSTER'S angle, *LIGHT curves, *GAMMA ray bursts, *PULSARS, *BINARY pulsars

Abstract

In so-called spider pulsars, the X-ray band is dominated by intrabinary shock (IBS) synchrotron emission. While the double-peaked X-ray light curves from these shocks have been well characterized in several spider systems (both black widows and redbacks), the polarization of this emission is yet to be studied. Motivated by the new polarization capability of the Imaging X-ray Polarization Explorer and the confirmation of highly ordered magnetic fields in pulsar wind nebulae, we model the IBS polarization by employing two potential magnetic field configurations: toroidal magnetic fields imposed by the preshock pulsar wind, and tangential shock-generated fields that follow the postshock flow. We find that if IBSs host ordered magnetic fields, the synchrotron X-rays from spider binaries can display a high degree of polarization (≳50%), while the variation in polarization angle provides a good probe of the binary geometry and the magnetic field structure. Our results encourage observational polarization studies of spider pulsars that can distinguish the proposed magnetic models and that constrain the unique properties of these systems better. [ABSTRACT FROM AUTHOR]

Published

2023

44. Astrophysical Appearance of Primordial Black Holes.

Author

Postnov, K. A., Kuranov, A. G., and Mitichkin, N. A.

Subjects

*BLACK holes, *MASS spectrometry, *BINARY black holes, *BINARY pulsars, *GRAVITATIONAL waves, *OBSERVATORIES

Abstract

Interest to astrophysical evidence for primordial black holes (PBHs) formed in the early Universe from initial cosmological perturbations has increased after the discovery of coalescing binary black holes with masses more than dozen solar ones by gravitational-wave (GW) observatories. We briefly discuss increasing evidence that PBHs can provide some fraction of detected merging binary BHs and can be related to an isotropic stochastic GW background recently discovered by pulsar timing arrays. We focus on PBHs with log-normal mass spectrum originated from isocurvature perturbations in the modified Affleck–Dine baryogenesis scenario by Dolgov and Silk (1993). We show that almost equal populations of astrophysical binary BHs from massive binary evolution and binary PBHs with log-normal mass spectrum can describe both the observed chirp mass distribution and effective spin—mass ratio anti-correlation of the LVK binary BHs. [ABSTRACT FROM AUTHOR]

Published

2023

45. Variability, polarimetry, and timing properties of single pulses from PSR J2222−0137 using FAST.

Author

Miao, X L, Zhu, W W, Kramer, M, Freire, P C C, Shao, L, Yuan, M, Meng, L Q, Wu, Z W, Miao, C C, Guo, Y J, Champion, D J, Fonseca, E, Yao, J M, Xue, M Y, Niu, J R, Hu, H, and Zhang, C M

Subjects

*BINARY pulsars, *LOGNORMAL distribution, *POLARIMETRY, *PULSARS, *RADIO telescopes, *TESTING laboratories

Abstract

In our work, we analyse 5 × 104 single pulses from the recycled pulsar PSR J2222−0137 in one of its scintillation maxima observed by the Five-hundred-meter Aperture Spherical radio Telescope (FAST). PSR J2222−0137 is one of the nearest and best studies of binary pulsars and a unique laboratory for testing gravitational theories. We report single pulses' energy distribution and polarization from the pulsar's main-pulse region. The single-pulse energy follows the lognormal distribution. We resolve a steep polarization swing, but at the current time resolution (⁠|$64\ \mu {\rm s}$|⁠), we find no evidence for the orthogonal jump in the main-pulse region, as has been suspected. We find a potential sub-pulse drifting period of |$P_{3} \sim 3.5 P$|⁠. We analyse the jitter noise from different integrated numbers of pulses and find that its σj is |$270\pm {9}\ {\rm ns}$| for 1-h integration at 1.25 GHz. This result is useful for optimizing future timing campaigns with FAST or other radio telescopes. [ABSTRACT FROM AUTHOR]

Published

2023

46. The FAST Galactic Plane Pulsar Snapshot Survey – III. Timing results of 30 newly discovered pulsars.

Author

Su, W Q, Han, J L, Wang, P F, Yuan, J P, Wang, Chen, Zhou, D J, Wang, Tao, Yan, Yi, Jing, W C, Yang, Z L, Cai, N N, Chen, Xue, Xu, Jun, Xie, Lang, Wang, H G, Xu, R X, and You, X P

Subjects

*RADIO telescopes, *PULSARS, *ACTINIC flux, *BINARY pulsars, *MAGNETIC fields, PULSAR detection

Abstract

Timing observations are crucial for determining the basic parameters of newly discovered pulsars. Using the Five-hundred-meter Aperture Spherical radio Telescope (FAST) with the L-band 19-beam receiver covering the frequency range of 1.0–1.5 GHz, the FAST Galactic Plane Pulsar Snapshot (GPPS) Survey has discovered more than 600 faint pulsars with flux densities of only a few or a few tens of μJy at 1.25 GHz. To obtain accurate position, spin parameters and dispersion measure of a pulsar, and to calculate derived parameters such as the characteristic age and surface magnetic field, we collect available FAST pulsar data obtained either through targeted follow-up observations or through coincidental survey observations with one of the 19 beams of the receiver. From these data we obtain time of arrival (TOA) measurements for 30 newly discovered pulsars as well as for 13 known pulsars. We demonstrate that the TOA measurements acquired by the FAST from any beams of the receiver in any observation mode (e.g. the tracking mode or the snapshot mode) can be combined to get timing solutions. We update the ephemerides of 13 previously known pulsars and obtain the first phase-coherent timing results for 30 isolated pulsars discovered in the FAST GPPS Survey. Notably, PSR J1904+0853 is an isolated millisecond pulsar, PSR J1906+0757 is a disrupted recycled pulsar, and PSR J1856+0211 has a long period of 9.89 s that can constrain pulsar death lines. Based on these timing solutions, all available FAST data have been added together to obtain the best pulse profiles for these pulsars. [ABSTRACT FROM AUTHOR]

Published

2023

47. 4FGL J2054.2+6904: A Binary "Redback" Pulsar.

Author

Zyuzin, D. A., Karpova, A. V., Shibanov, Yu. A., and Gilfanov, M. R.

Subjects

*SPECTRAL energy distribution, *NEUTRON stars, *BINARY pulsars, *X-ray spectra, *STELLAR spectra

Abstract

The γ-ray source 4FGL J2054.2+6904 discovered with Fermi was recently classified as a pulsar candidate. Its possible X-ray and optical counterpart was identified with Swift. Using Zwicky survey data we show that the counterpart is variable in the optical with the period of about 7.5 h. The shape of the light curve is almost sinusoidal with the amplitude of ≈0.5m. The spectral energy distribution corresponds to the stellar spectrum with the effective temperature of 5820 ± 410 K. We also firmly detected the source in X-rays using the SRG/eROSITA all sky survey data. Its X-ray spectrum can be described by a power law with the photon index of about 1.0 and unabsorbed flux ≈2 × 10–13 erg/(s cm2) in the 0.5–10 keV range. These results show that 4FGL J2054.2+6904 is a promising candidate to a millisecond pulsar in a close binary system of the "redback" type. [ABSTRACT FROM AUTHOR]

Published

2024

48. The Neutron Star Mass, Distance, and Inclination from Precision Timing of the Brilliant Millisecond Pulsar J0437-4715

Author

Daniel J. Reardon, Matthew Bailes, Ryan M. Shannon, Chris Flynn, Jacob Askew, N. D. Ramesh Bhat, Zu-Cheng Chen, Małgorzata Curyło, Yi Feng, George B. Hobbs, Agastya Kapur, Matthew Kerr, Xiaojin Liu, Richard N. Manchester, Rami Mandow, Saurav Mishra, Christopher J. Russell, Mohsen Shamohammadi, Lei Zhang, and Andrew Zic

Subjects

Millisecond pulsars, Binary pulsars, Pulsar timing method, Radio pulsars, Neutron stars, Neutron star cores, Astrophysics, QB460-466

Abstract

The observation of neutron stars enables the otherwise impossible study of fundamental physical processes. The timing of binary radio pulsars is particularly powerful, as it enables precise characterization of their (three-dimensional) positions and orbits. PSR J0437–4715 is an important millisecond pulsar for timing array experiments and is also a primary target for the Neutron Star Interior Composition Explorer (NICER). The main aim of the NICER mission is to constrain the neutron star equation of state by inferring the compactness ( M _p / R ) of the star. Direct measurements of the mass M _p from pulsar timing therefore substantially improve constraints on the radius R and the equation of state. Here we use observations spanning 26 yr from Murriyang, the 64 m Parkes radio telescope, to improve the timing model for this pulsar. Among the new precise measurements are the pulsar mass M _p = 1.418 ± 0.044 M _⊙ , distance D = 156.96 ± 0.11 pc, and orbital inclination angle i = 137.°506 ± 0.°016, which can be used to inform the X-ray pulse profile models inferred from NICER observations. We demonstrate that these results are consistent between multiple data sets from the Parkes Pulsar Timing Array (PPTA), each modeled with different noise assumptions. Using the longest available PPTA data set, we measure an apparent second derivative of the pulsar spin frequency and discuss how this can be explained either by kinematic effects due to the proper motion and radial velocity of the pulsar or excess low-frequency noise such as a gravitational-wave background.

Published

2024

49. A Millisecond Pulsar Binary Embedded in a Galactic Center Radio Filament

Author

Marcus E. Lower, Shi Dai, Simon Johnston, and Ewan D. Barr

Subjects

Binary pulsars, Galactic center, Interstellar filaments, Pulsars, Astrophysics, QB460-466

Abstract

The Galactic center is host to a population of extraordinary radio filaments, thin linear structures that trace out magnetic field lines running perpendicular to the Galactic plane. Using Murriyang, the 64 m Parkes radio telescope, we conducted a search for pulsars centered on the position of a compact source in the filament G359.0−0.2. We discovered a millisecond pulsar (MSP), PSR J1744−2946, with a period P = 8.4 ms, that is bound in a 4.8 hr circular orbit around an M _c > 0.05 M _⊙ companion. The pulsar dispersion measure of 673.7 ± 0.1 pc cm ^−3 and Faraday rotation measure of 3011 ± 3 rad m ^−2 are the largest of any known MSP. Its radio pulses are moderately scattered due to multipath propagation through the interstellar medium, with a scattering timescale of 0.87 ± 0.08 ms at 2.6 GHz. Using MeerKAT, we localized the pulsar to a point source embedded in a low-luminosity radio filament, the “Sunfish”, that is unrelated to G359.0−0.2. Our discovery of the first MSP within 1° of the Galactic center hints at a large population of these objects detectable via high-frequency surveys. The association with a filament points to pulsars as the energy source responsible for illuminating the Galactic center radio filaments.

Published

2024

50. A Relativistic Double Neutron Star Binary PSR J1846-0513

Author

D. Zhao, N. Wang, J. P. Yuan, D. Li, P. Wang, M. Y. Xue, W. W. Zhu, C. C. Miao, W. M. Yan, J. B. Wang, J. M. Yao, Q. D. Wu, S. Q. Wang, S. N. Sun, F. F. Kou, Y. T. Chen, S. J. Dang, Y. Feng, Z. J. Liu, X. L. Miao, L. Q. Meng, M. Yuan, C. H. Niu, J. R. Niu, L. Qian, S. Wang, X. Y. Xie, Y. F. Xiao, Y. L. Yue, S. P. You, X. H. Yu, R. S. Zhao, R. Yuen, X. Zhou, L. Zhang, Y. B. Wang, J. F. Wu, Z. Y. Gan, Z. Y. Sun, and C. J. Wang

Subjects

Binary pulsars, Pulsars, Astrophysics, QB460-466

Abstract

We report the timing analysis of PSR J1846−0513, a pulsar discovered by the Five-hundred-meter Aperture Spherical radio Telescope (FAST) in Commensal Radio Astronomy FAST Survey. The pulsar possesses a spin period of 23.36 ms and a spin-down rate ( $\dot{P}$ ) of 1.0106(3) × 10 ^−18 s s ^−1 , and it is located in an eccentric orbit ( e ∼0.208) with an orbital period of 0.61 days. The characteristic age and surface magnetic field of the pulsar are found to be 366.62 Myr and 4.9178 × 10 ^9 G, respectively, indicating that it is a recycled pulsar. Using over two years of timing data, we measure the periastron advance $\dot{\omega }$ = 0.8956(8) deg yr ^−1 . By assuming that this effect is purely relativistic, we have estimated the total mass M = 2.6287(35) M _⊙ and obtained an upper limit for the pulsar mass and a lower limit for the companion’s mass. Our results indicate that this is a double neutron star system.

Published

2024