Your search keyword '"Stars: Neutron"' showing total 7,304 results

1. Timing analysis of Be/X-ray transient 4U 0115 + 63 during Type II outburst of 2023 using NuSTAR observations

Author

Jain, Chetana, Sharma, Prince, and Dutta, Anjan

Published

2025

2. Comprehensive spectro-temporal studies of GX 17+2 using AstroSat observations

Author

Thomas, Neal Titus, Lavanya, S., Gudennavar, S.B., and Bubbly, S.G.

Published

2025

3. A GTC spectroscopic study of three spider pulsar companions: line-based temperatures, a new face-on redback, and improved mass constraints.

Author

Simpson, Jordan A, Linares, Manuel, Casares, Jorge, Shahbaz, Tariq, Sen, Bidisha, and Camilo, Fernando

Subjects

*NEUTRON stars, *OPTICAL spectroscopy, *ORBITS (Astronomy), *PULSARS, *VELOCITY

Abstract

We present GTC-OSIRIS phase-resolved optical spectroscopy of three compact binary millisecond pulsars, or 'spiders': PSR J1048+2339, PSR J1810+1744, and (for the first time) PSR J1908+2105. For the companion in each system, the temperature is traced throughout its orbit, and radial velocities are measured. The radial velocities are found to vary with the absorption features used when measuring them, resulting in different radial velocity curve semi-amplitudes: for J1048 (⁠|$K_\mathrm{metals, red} = 344 \pm 4{\mathrm{\, km\, s^{-1}}}{}$| and |$K_\mathrm{metals, blue} = 372 \pm 3{\mathrm{\, km\, s^{-1}}}{}$|⁠) and, tentatively, for J1810 (⁠|$K_\mathrm{Balmer} = 448 \pm 19{\mathrm{\, km\, s^{-1}}}{}$| and |$K_\mathrm{metals} = 491 \pm 32{\mathrm{\, km\, s^{-1}}}{}$|⁠). With existing inclination constraints, this gives the neutron star (NS) and companion masses |$M_\mathrm{NS} = 1.50$| – |$2.04{\, {\rm M}_{\odot }}{}$| and |$M_2 = 0.32$| – |$0.40{\, {\rm M}_{\odot }}{}$| for J1048, and |$M_\mathrm{NS} \gt 1.7{\, {\rm M}_{\odot }}{}$| and |$M_2 = 0.05$| – |$0.08{\, {\rm M}_{\odot }}{}$| for J1810. For J1908, we find an upper limit of |$K_2 \lt 32{\mathrm{\, km\, s^{-1}}}{}$|⁠ , which constrains its mass ratio |$q = M_2 / M_\mathrm{NS} \gt 0.55$| and inclination |$i \lt 6.0^\circ$|⁠ , revealing the previously misunderstood system to be the highest mass ratio, lowest inclination redback yet. This raises questions for the origins of its substantial radio eclipses. Additionally, we find evidence of asymmetric heating in J1048 and J1810, and signs of metal enrichment in J1908. We also explore the impact of inclination on spectroscopic temperatures, and demonstrate that the temperature measured at quadrature (⁠|$\phi = 0.25\,\mathrm{ and}\,0.75$|⁠) is essentially independent of inclination, and thus can provide additional constraints on photometric modelling. [ABSTRACT FROM AUTHOR]

Published

2025

4. Neutron star g modes in the relativistic Cowling approximation.

Author

Counsell, A R, Gittins, F, Andersson, N, and Pnigouras, P

Subjects

*STELLAR oscillations, *GRAVITATIONAL wave detectors, *LOW mass stars, *NEUTRON stars, *NUCLEAR matter

Abstract

Mature neutron stars are expected to exhibit gravity g modes due to stratification caused by a varying matter composition in the high-density core. By employing the BSk equation-of-state family, and working within the relativistic Cowling approximation, we examine how subtle differences in the nuclear matter assumptions impact on the g-mode spectrum. We investigate the possibility of detecting individual g-mode resonances during a binary inspiral with current and next-generation ground-based detectors, like Cosmic Explorer and the Einstein Telescope. Our results suggest that these resonances may be within the reach of future detectors, especially for low-mass stars with |$M\lesssim 1.4\,\mathrm{ M}_\odot$|⁠. [ABSTRACT FROM AUTHOR]

Published

2025

5. AstroSat timing and spectral analysis of the accretion-powered millisecond X-ray pulsar IGR J17591–2342.

Author

Singh, Akshay, Sanna, Andrea, Bhattacharyya, Sudip, Chakraborty, Sudip, Jangle, Sarita, Katoch, Tilak, Antia, H M, and Bijewar, Nitinkumar

Subjects

*NEUTRON stars, *PHOTON scattering, *X-ray telescopes, *X-ray binaries, *ACCRETION disks

Abstract

IGR J17591–2342, a transient accretion-powered millisecond X-ray pulsar, was discovered during its 2018 outburst. Here, we present a timing and spectral analysis of the source using AstroSat data of the same outburst. From the timing analysis, we obtain updated values of binary orbital parameters, which reveal an average pulsar spin frequency of 527.425 6984(8) Hz. The pulse profiles can be fit well with four harmonically related sinusoidal components with fractional amplitudes of fundamental and second, third, and fourth harmonics as ~13 per cent, ~6 per cent, ~0.9 per cent, and ~0.2 per cent, respectively. The energy-dependent study of pulse profiles in the range of 3–20 keV shows that the fractional amplitude of both the fundamental and first overtone is consistent with being constant across the considered energy band. Besides, a decaying trend has been observed for both the fundamental and first overtone in the phase-delay versus energy relation, resulting in soft X-ray (2.8–3.3 keV) phase lags of |$\sim$| 0.05 and |$\sim$| 0.13 with respect to |$\le 15$|  keV photons, for the fundamental and first overtone, respectively. The combined spectra from the Large Area X-ray Proportional Counters and the Soft X-ray Telescope aboard AstroSat in the 1–18 keV range can be fit well with an absorbed model consisting of a Comptonization, a blackbody and a Gaussian emission-line component yielding as best-fitting parameters a blackbody seed photon temperature |$kT_{\rm bb}$| |$\sim 0.95 \pm 0.03$| keV, and an electron temperature |$kT_{\rm e}$| |$\sim 1.54 \pm 0.03$| keV. The spectral aspects suggest the scattering of photons from the accretion disc or the neutron star's surface. [ABSTRACT FROM AUTHOR]

Published

2025

6. Application of Kaluza–Klein theory in modelling compact stars: exploring extra dimensions.

Author

Horváth, Anna, Forgács-Dajka, Emese, and Barnaföldi, Gergely Gábor

Subjects

*COMPACT objects (Astronomy), *NEUTRON stars, *STELLAR mass, *EQUATIONS of state, *PULSARS

Abstract

A theoretical framework for calculating the mass–radius curve of compact stars in the Kaluza–Klein space–time is introduced, with one additional compact spatial dimension. Static, spherically symmetric solutions are considered, with the equation of state provided by a zero temperature, interacting multidimensional Fermi gas. To model the strong force between baryons, a repulsive potential is introduced, which is linear in the particle number density. The maximal mass of compact stars is calculated for different model parameters, and with a physical parameter choice, it satisfies observational data, meaning that it is possible to model simple, realistic objects within this framework. Based on this comparison, a limiting size for the observational regime of extra dimensions in compact stars is provided, with |$r_\mathrm{c} \gtrsim 0.2$|  fm. [ABSTRACT FROM AUTHOR]

Published

2025

7. Three-dimensional magnetohydrodynamic simulations of core-collapse supernovae – I. Hydrodynamic evolution and protoneutron star properties.

Author

Nakamura, Ko, Takiwaki, Tomoya, Matsumoto, Jin, and Kotake, Kei

Subjects

*STELLAR magnetic fields, *SUPERGIANT stars, *STELLAR mass, *STELLAR evolution, *NEUTRON stars

Abstract

We present results from three-dimensional, magnetohydrodynamic, core-collapse simulations of 16 progenitors following until 0.5 s after bounce. We use non-rotating solar-metallicity progenitor models with zero-age main-sequence mass between 9 and 24 |${\rm M}_{\odot }$|⁠. The examined progenitors cover a wide range of the compactness parameter including a peak around |$23 \, {\rm M}_{\odot }$|⁠. We find that neutrino-driven explosions occur for all models within 0.3 s after bounce. We also find that the properties of the explosions and the central remnants are well correlated with the compactness. Early shock evolution is sensitive to the mass accretion rate on to the central core, reflecting the density profile of the progenitor stars. The most powerful explosions with diagnostic explosion energy |$E_{\rm dia} \sim 0.75 \times 10^{51}$| erg are obtained by 23 and 24 |${\rm M}_{\odot }$| models, which have the highest compactness among the examined models. These two models exhibit spiral standing-accretion-shock-instability motions during 150–230 ms after bounce preceding a runaway shock expansion and leave a rapidly rotating neutron star with spin periods |$\sim 50$| ms. Our models predict the gravitational masses of the neutron star ranging between |$1.22$| and |$1.67 {\rm M}_{\odot }$| and their spin periods 0.04 – 4 s. The number distribution of these values roughly matches observation. On the other hand, our models predict small hydrodynamic kick velocity (15–260  |${\rm km \, s}^{-1}$|⁠), although they are still growing at the end of our simulations. Further systematic studies, including rotation and binary effects, as well as long-term simulations up to several seconds, will enable us to explore the origin of various core-collapse supernova explosions. [ABSTRACT FROM AUTHOR]

Published

2025

8. Simultaneous radio and X-ray observations of the transitional millisecond pulsar candidate 3FGL J1544.6−1125.

Author

Gusinskaia, N V, Jaodand, A D, Hessels, J W T, Bogdanov, S, Deller, A T, Miller-Jones, J C A, Russell, T D, Patruno, A, and Archibald, A M

Subjects

*X-ray binaries, *NEUTRON stars, *RADIO programs, *PULSARS, *X-rays

Abstract

Transitional millisecond pulsars (tMSPs) are neutron star systems that alternate between a rotation-powered radio millisecond pulsar state and an accretion disc-dominated low-mass X-ray binary (LMXB)-like state on multi-year time-scales. During the LMXB-like state, the X-ray emission from tMSPs switches between 'low' and 'high' X-ray brightness modes on a time-scale of seconds to minutes (or longer), while the radio emission shows variability on time-scales of roughly minutes. Coordinated Very Large Array (VLA) and Chandra observations of the nearby tMSP PSR J1023+0038 uncovered a clear anticorrelation between radio and X-ray luminosities such that the radio emission consistently peaks during the X-ray low modes. In addition, there are sometimes also radio/X-ray flares that show no obvious correlation. In this paper, we present simultaneous radio and X-ray observations of a promising tMSP candidate system, 3FGL J1544.6 |$-$| 1125, which shows optical, |$\gamma$| -ray, and X-ray phenomena similar to PSR J1023+0038, but which is challenging to study because of its greater distance. Using simultaneous VLA and Chandra observations, we find that the radio and X-ray emission are consistent with being anticorrelated in a manner similar to PSR J1023+0038. We discuss how our results help in understanding the origin of bright radio emission from tMSPs. The greater sensitivity of upcoming telescopes such as the Square Kilometre Array will be crucial for studying the correlated radio/X-ray phenomena of tMSP systems. [ABSTRACT FROM AUTHOR]

Published

2025

9. Spectral analysis of ultraluminous X-ray pulsars with models of X-ray pulsars.

Author

Kumar, Manish, Sharma, Rahul, Paul, Biswajit, and Rana, Vikram

Subjects

*BINARY black holes, *X-ray spectra, *NEUTRON stars, *BLACK holes, *MAGELLANIC clouds

Abstract

A fraction of the ultraluminous X-ray (ULX) sources are known to be accreting neutron stars as they show coherent X-ray pulsations with pulse periods ranging from |${\sim} 1{\!-\!}30$|  s. While initially thought to host intermediate-mass black holes, ULXs have since been recognized as a diverse class of objects, including ULX pulsars. These pulsars require models specifically tailored to account for their unique accretion physics, distinct from those used for Galactic black hole binaries. The X-ray spectra of all Galactic accreting X-ray pulsars (including sources in the Magellanic Clouds) are dominated by a high-energy cut-off power law and some of the sources show a soft excess, some emission lines, cyclotron absorption features, etc. In this work, we undertake a comprehensive analysis of the broad-band X-ray spectra of five ULX pulsars using simultaneous XMM – Newton and NuSTAR observations and show that their X-ray spectra can be effectively described by spectral models, similar to those used for the local accretion-powered X-ray pulsars. A soft excess is detected in all the sources which is also consistent with the local X-ray pulsars that have low absorption column density. We have marginal detection or low upper limit on the presence of the iron K-alpha emission line from these sources, which is a key difference of the ULX pulsars with the local accreting X-ray pulsars. We discuss the implication of this on the nature of the binary companion and the accretion mechanism in the ULX pulsars. [ABSTRACT FROM AUTHOR]

Published

2025

10. Three dimensional end-to-end simulation for kilonova emission from a black hole neutron star merger.

Author

Kawaguchi, Kyohei, Domoto, Nanae, Fujibayashi, Sho, Hamidani, Hamid, Hayashi, Kota, Shibata, Masaru, Tanaka, Masaomi, and Wanajo, Shinya

Subjects

*LONG-Term Evolution (Telecommunications), *NUCLEAR reactions, *LIGHT curves, *NEUTRON stars, *BLACK holes

Abstract

We study long-term evolution of the matter ejected in a black hole neutron star (BH–NS) merger employing the results of a long-term numerical-relativity simulation and nucleosynthesis calculation, in which both dynamical and post-merger ejecta formation is consistently followed. In particular, we employ the results for the merger of a |$1.35\, \mathrm{ M}_\odot$| NS and a |$5.4\, \mathrm{ M}_\odot$| BH with the dimensionless spin of 0.75. We confirm the finding in the previous studies that thermal pressure induced by radioactive heating in the ejecta significantly modifies the morphology of the ejecta. We then compute the kilonova (KN) light curves employing the ejecta profile obtained by the long-term evolution. We find that our present BH–NS model results in a KN light curve that is fainter yet more enduring than that observed in AT2017gfo. This is due to the fact that the emission is primarily powered by the lanthanide-rich dynamical ejecta, in which a long photon diffusion time-scale is realized by the large mass and high opacity. While the peak brightness of the KN emission in both the optical and near-infrared bands is fainter than or comparable to those of binary NS models, the time-scale maintaining the peak brightness is much longer in the near-infrared band for the BH–NS KN model. Our result indicates that a BH–NS merger with massive ejecta can observationally be identified by the long lasting (> two weeks) near-infrared emission. [ABSTRACT FROM AUTHOR]

Published

2024

11. Probing the origin of the extended flaring branch of Z-type X-ray binaries GX 340+0 and GX 5-1 using AstroSat.

Author

Dutta, Tanmoy, Pahari, Mayukh, Sarkar, Anish, Bhattacharyya, Sudip, and Bhargava, Yash

Subjects

*X-ray binaries, *BLACKBODY radiation, *NEUTRON stars, *BOUNDARY layer (Aerodynamics), *ACCRETION disks

Abstract

'Z' type neutron star low-mass X-ray binaries typically show a 'Z'-like three-branched track in their hardness intensity diagram. However, a few such 'Z' sources show an additional branch known as the extended flaring branch (EFB). EFB has been poorly studied, and its origin is not known. It is thought to be an extension of the flaring branch (FB) or associated with Fe K  |$\alpha$| complex or an additional continuum due to the radiative recombination continuum (RRC) process. Using AstroSat observations, we have detected the EFB from two 'Z' sources, GX 340+0 and GX 5–1, and performed a broad-band spectral analysis in the 0.5–22 keV energy range. During EFB, both sources show the presence of a significant RRC component with absorption edges at |$7.91^{+0.16}_{-0.15}$| and |$8.10^{+0.16}_{-0.17}$|  keV, respectively along with blackbody radiation and thermal Comptonization. No signature of RRC was detected during the FB, which is adjoint to the EFB. No Fe K  |$\alpha$| complex is detected. Interestingly, inside EFB dips of GX 5-1, for the first time, we have detected flaring events of 30–60 s, which can be modelled with a single blackbody radiation. During the FB to EFB transition, an increase in the blackbody radius by a factor of 1.5–2 is observed in both sources. Our analysis strongly suggests that EFB is not an extension of FB or caused by the Fe K  |$\alpha$| complex. Rather, it is caused by a sudden expansion of the hot, thermalized boundary layer and subsequent rapid cooling. [ABSTRACT FROM AUTHOR]

Published

2024

12. The Meissner effect in neutron stars.

Author

Lander, S K

Subjects

*MEISSNER effect, *MAGNETIC reconnection, *NEUTRON stars, *MAGNETIC fields, *MAGNETIC flux

Abstract

We present the first model aimed at understanding how the Meissner effect in a young neutron star affects its macroscopic magnetic field. In this model, field expulsion occurs on a dynamical time-scale, and is realized through two processes that occur at the onset of superconductivity: fluid motions causing the dragging of field lines, followed by magnetic reconnection. Focusing on magnetic fields weaker than the superconducting critical field, we show that complete Meissner expulsion is but one of four possible generic scenarios for the magnetic-field geometry, and can never expel magnetic flux from the centre of the star. Reconnection causes the release of up to |$\sim 5\times 10^{46}\, \mathrm{erg}$| of energy at the onset of superconductivity, and is only possible for certain favourable early-phase dynamics and for pre-condensation fields |$10^{12}\, \mathrm{G}\lesssim B\lesssim 5\times 10^{14}\, \mathrm{G}$|⁠. Fields weaker or stronger than this are predicted to thread the whole star. [ABSTRACT FROM AUTHOR]

Published

2024

13. Constraining accreted neutron star crust shallow heating with the inferred depth of carbon ignition in X-ray superbursts.

Author

Meisel, Zach

Subjects

*NUCLEAR fusion, *NUCLEAR reactions, *NEUTRON stars, *NUCLEOSYNTHESIS, *HEATING

Abstract

Evidence has accumulated for an as-yet unaccounted for source of heat located at shallow depths within the accreted neutron star crust. However, the nature of this heat source is unknown. I demonstrate that the inferred depth of carbon ignition in X-ray superbursts can be used as an additional constraint for the magnitude and depth of shallow heating. The inferred shallow heating properties are relatively insensitive to the assumed crust composition and carbon fusion reaction rate. For low-accretion rates, the results are weakly dependent on the duration of the accretion outburst, so long as accretion has ensued for enough time to replace the ocean down to the superburst ignition depth. For accretion rates at the Eddington rate, results show a stronger dependence on the outburst duration. Consistent with earlier work, it is shown that urca cooling does not impact the calculated superburst ignition depth unless there is some proximity in depth between the heating and cooling sources. [ABSTRACT FROM AUTHOR]

Published

2024

14. Mass and spin measurements of black hole and neutron stars X-ray binaries through axisymmetric oscillation modes of thick torus.

Author

Trova, Audrey

Subjects

*ANGULAR momentum (Mechanics), *BLACK holes, *NEUTRON stars, *ACCRETION disks, *MOMENTUM distributions, *STELLAR oscillations, *X-ray binaries

Abstract

This paper examines the oscillatory behaviour of relativistic, non-self-gravitating, charged-fluid toroidal structures within the context of the Kerr metric. The primary objective is to explore how thick accretion discs influence the mass and spin measurements of black holes and neutron stars in low-mass X-ray binaries (LMXBs) through quasi-periodic oscillations (QPOs) models. To achieve this, we conduct a local analysis within a general relativistic framework, determining the radial epicyclic and orbital frequencies in a perfect fluid disc. The tori are modelled using a non-Keplerian distribution of specific angular momentum, and we analyse how the oscillation properties depend on the model's angular momentum distribution parameters. Subsequently, we connect these oscillatory frequencies to high-frequency QPOs observed in LMXBs, enabling us to calculate the optimal mass and spin values for each studied source. [ABSTRACT FROM AUTHOR]

Published

2024

15. A two-minute burst of highly polarized radio emission originating from low Galactic latitude.

Author

Dobie, Dougal, Zic, Andrew, Oswald, Lucy S, Pritchard, Joshua, Lower, Marcus E, Wang, Ziteng, Qiu, Hao, Hurley-Walker, Natasha, Wang, Yuanming, Lenc, Emil, Kaplan, David L, Anumarlapudi, Akash, Auchettl, Katie, Bailes, Matthew, Cameron, Andrew D, Cooke, Jeffrey, Deller, Adam, Driessen, Laura N, Freeburn, James, and Murphy, Tara

Subjects

*NEUTRON stars, *PULSARS, *MILKY Way, *LATITUDE, *MORPHOLOGY

Abstract

Several sources of repeating coherent bursts of radio emission with periods of many minutes have now been reported in the literature. These 'ultralong period' (ULP) sources have no clear multiwavelength counterparts and challenge canonical pulsar emission models, leading to debate regarding their nature. In this work, we report the discovery of a bright, highly polarized burst of radio emission at low Galactic latitude as part of a wide-field survey for transient and variable radio sources. ASKAP J175534.9 |$-$| 252749.1 does not appear to repeat, with only a single intense two-minute |$\sim$| 200-mJy burst detected from 60 h of observations. The burst morphology and polarization properties are comparable to those of classical pulsars but the duration is more than one hundred times longer, analogous to ULPs. Combined with the existing ULP population, this suggests that these sources have a strong Galactic latitude dependence and hints at an unexplored population of transient and variable radio sources in the thin disc of the Milky Way. The resemblance of this burst with both ULPs and pulsars calls for a unified coherent emission model for objects with spin periods from milliseconds to tens of minutes. However, whether or not these are all neutron stars or have the same underlying power source remains open for debate. [ABSTRACT FROM AUTHOR]

Published

2024

16. Long-term evolution of spin and other properties of neutron star low-mass X-ray binaries: implications for millisecond X-ray pulsars.

Author

Kar, Abhijnan, Ojha, Pulkit, and Bhattacharyya, Sudip

Subjects

*NEUTRON stars, *LONG-Term Evolution (Telecommunications), *BROWN dwarf stars, *ACCRETION disks, *PULSARS, *X-ray binaries

Abstract

A neutron star (NS) accreting matter from a companion star in a low-mass X-ray binary (LMXB) system can spin up to become a millisecond pulsar (MSP). Properties of many such MSP systems are known, which is excellent for probing fundamental aspects of NS physics when modelled using the theoretical computation of NS LMXB evolution. Here, we systematically compute the long-term evolution of NS, binary, and companion parameters for NS LMXBs using the stellar evolution code mesa. We consider the baryonic to gravitational mass conversion to calculate the NS mass evolution and show its cruciality for the realistic computation of some parameters. With computations using many combinations of parameter values, we find the general nature of the complex NS spin frequency (⁠|$\nu$|⁠) evolution, which depends on various parameters, including accretion rate, fractional mass-loss from the system, and companion star magnetic braking. Further, we utilize our results to precisely match some main observed parameters, such as |$\nu$|⁠ , orbital period (⁠|$P_{\rm orb}$|⁠), etc. of four accreting millisecond X-ray pulsars (AMXPs). By providing the |$\nu$|⁠ , |$P_{\rm orb}$|⁠ , and the companion mass spaces for NS LMXB evolution, we indicate the distribution and plausible evolution of a few other AMXPs. We also discuss the current challenges in explaining the parameters of AMXP sources with brown dwarf companions and indicate the importance of modelling the transient accretion in LMXBs as a possible solution. [ABSTRACT FROM AUTHOR]

Published

2024

17. Magnetic coupling through flux branching of adjacent type-I and -II superconductors in a neutron star.

Author

Thong, K H and Melatos, A

Subjects

*MAGNETIC coupling, *STELLAR magnetic fields, *STELLAR evolution, *NEUTRON stars, *MAGNETIC moments

Abstract

The inner and outer cores of neutron stars are believed to contain type-I and -II proton superconductors, respectively. The type-I superconductor exists in an intermediate state, comprising macroscopic flux-free and flux-containing regions, while the type-II superconductor is flux-free, except for microscopic, quantized flux tubes. Here, we show that the inner and outer cores are coupled magnetically, when the macroscopic flux tubes subdivide dendritically into quantized flux tubes, a phenomenon called flux branching. An important implication is that up to |${\sim} 10^{12} (r_1/10^6 \, {\rm cm}) \, {\rm erg}$| of energy are required to separate a quantized flux tube from its progenitor macroscopic flux tube, where |$r_1$| is the length of the macroscopic flux tube. Approximating the normal-superconducting boundary as sharp, we calculate the magnetic coupling energy between a quantized and macroscopic flux tube due to flux branching as a function of, |$f_1$|⁠ , the radius of the type-I inner core divided by the radius of the type-II outer core. Strong coupling delays magnetic field decay in the type-II superconductor. For an idealized inner core containing only a type-I proton superconductor and poloidal flux, and in the absence of ambipolar diffusion and diamagnetic screening, the low magnetic moments (⁠|${\lesssim} 10^{27} \, {\rm G \, cm^3}$|⁠) of recycled pulsars imply |$f_1 \lesssim 10^{-1.5}$|⁠. [ABSTRACT FROM AUTHOR]

Published

2024

18. A dissipative extension to ideal hydrodynamics.

Author

Hatton, Marcus John and Hawke, Ian

Subjects

*EULER equations, *BULK viscosity, *EQUATIONS of motion, *STELLAR mergers, *NEUTRON stars

Abstract

We present a formulation of special relativistic dissipative hydrodynamics (SRDHD) derived from the well-established Müller–Israel–Stewart (MIS) formalism using an expansion in deviations from ideal behaviour. By re-summing the non-ideal terms, our approach extends the Euler equations of motion for an ideal fluid through a series of additional source terms that capture the effects of bulk viscosity, shear viscosity, and heat flux. For efficiency these additional terms are built from purely spatial derivatives of the primitive fluid variables. The series expansion is parametrized by the dissipation strength and time-scale coefficients, and is therefore rapidly convergent near the ideal limit. We show, using numerical simulations, that our model reproduces the dissipative fluid behaviour of other formulations. As our formulation is designed to avoid the numerical stiffness issues that arise in the traditional MIS formalism for fast relaxation time-scales, it is roughly an order of magnitude faster than standard methods near the ideal limit. [ABSTRACT FROM AUTHOR]

Published

2024

19. MeerKAT observations of pair-plasma induced birefringence in the double pulsar eclipses.

Author

Lower, M E, Kramer, M, Johnston, S, Breton, R P, Wex, N, Bailes, M, Buchner, S, Camilo, F, Oswald, L S, Reardon, D J, Shannon, R M, Serylak, M, and Krishnan, V Venkatraman

Subjects

*NEUTRON stars, *LINEAR polarization, *CIRCULAR polarization, *LIGHT curves, *BREWSTER'S angle

Abstract

PSR J0737−3039A/B is unique among double neutron star systems. Its near-perfect edge-on orbit causes the fast spinning pulsar A to be eclipsed by the magnetic field of the slow spinning pulsar B. Using high-sensitivity MeerKAT radio observations combined with updated constraints on the system geometry, we studied the impact of these eclipses on the incident polarization properties of pulsar A. Averaging light curves together after correcting for the rotation of pulsar B revealed enormous amounts of circular polarization and rapid changes in the linear polarization position angle, which occur at phases where emission from pulsar A is partially transmitted through the magnetosphere of pulsar B. These behaviours confirm that the eclipse mechanism is the result of synchrotron absorption in a relativistic pair-plasma confined to the closed-field region of pulsar B's truncated dipolar magnetic field. We demonstrate that changes in circular polarization handedness throughout the eclipses are directly tied to the average line of sight magnetic field direction of pulsar B, from which we unambiguously determine the complete magnetic and viewing geometry of the pulsar. [ABSTRACT FROM AUTHOR]

Published

2024

20. Collisional and radiative data for tellurium ions in kilonovae modelling and laboratory benchmarks.

Author

Mulholland, L P, McNeill, F, Sim, S A, Ballance, C P, and Ramsbottom, C A

Subjects

*ENERGY levels (Quantum mechanics), *ATOMIC structure, *RADIATIVE transfer, *NEUTRON stars, *LOW temperatures

Abstract

Tellurium is a primary candidate for the identification of the 2.1  |$\, \mu$| m emission line in kilonovae (KNe) spectra AT2017gfo and GRB230307A. Despite this, there is currently an insufficient amount of atomic data available for this species. We calculate the required atomic structure and collisional data, particularly the data required for accurate non-local-thermodynamic-equilibrium (NLTE) modelling of the low temperatures and densities in KNe. We use a multiconfigurational Dirac–Hartree–Fock method to produce optimized one-electron orbitals for Te i - iii. As a result energy levels and Einstein A-coefficients for Te i - iii have been calculated. These orbitals are then employed within Dirac R -matrix collision calculations to provide electron-impact-excitation collision strengths that were subsequently averaged according to a thermal Maxwellian distribution. Subsequent tardis simulations using this new atomic data reveal no significant changes to the synthetic spectra due to the very minor contribution of Te at early epochs. NLTE simulations with the colradpy package reveal optically thin spectra consistent with the increasing prominence of the Te iii 2.1 |$\, \mu$| m line as the KNe ejecta cools. This is reinforced by the estimation of luminosities at nebular KNe conditions. New line ratios for both observation and laboratory benchmarks of the atomic data are proposed. [ABSTRACT FROM AUTHOR]

Published

2024

21. Formation of a magnetized hybrid star with a purely toroidal field from phase-transition-induced collapse.

Author

Yip, Anson Ka Long, Cheong, Patrick Chi-Kit, and Li, Tjonnie Guang Feng

Subjects

*STELLAR magnetic fields, *MAGNETIC flux density, *GRAVITATIONAL collapse, *PHASE transitions, *NEUTRON stars

Abstract

Strongly magnetized neutron stars are popular candidates for producing detectable electromagnetic and gravitational-wave signals. Gravitational collapses of neutron stars triggered by a phase transition from hadrons to deconfined quarks in the cores could also release a considerable amount of energy in the form of gravitational waves and neutrinos. Hence, the formation of a magnetized hybrid star from such a phase-transition-induced collapse is an interesting scenario for detecting all these signals. These detections may provide essential probes for the magnetic field and composition of such stars. Thus far, a dynamical study of the formation of a magnetized hybrid star from a phase-transition-induced collapse has yet to be realized. Here, we investigate the formation of a magnetized hybrid star with a purely toroidal field and its properties through dynamical simulations. We find that the maximum values of rest-mass density and magnetic field strength increase slightly and these two quantities are coupled in phase during the formation. We then demonstrate that all microscopic and macroscopic quantities of the resulting hybrid star vary drastically when the maximum magnetic field strength goes beyond a threshold of |$\sim 5 \times 10^{17}$| G, but they are insensitive to the magnetic field below this threshold. Specifically, the magnetic deformation makes the rest-mass density drop significantly, suppressing the matter fraction in the mixed phase. These behaviours agree with those in the equilibrium models of previous studies. Therefore, this work provides a solid support for the magnetic effects on a hybrid star. [ABSTRACT FROM AUTHOR]

Published

2024

22. TRAPUM pulsar and transient search in the Sextans A and B galaxies and discovery of background FRB 20210924D.

Author

Carli, E, Levin, L, Stappers, B W, Barr, E D, Breton, R P, Buchner, S, Burgay, M, Kramer, M, Padmanabh, P V, Possenti, A, Venkatraman Krishnan, V, Sridhar, S S, and Turner, J D

Subjects

*LARGE magellanic cloud, *SMALL magellanic cloud, *RADIO galaxies, *DWARF galaxies, *NEUTRON stars

Abstract

The Small and Large Magellanic Clouds are the only galaxies outside our own in which radio pulsars have been discovered to date. The sensitivity of the MeerKAT radio interferometer offers an opportunity to search for a population of more distant extragalactic pulsars. The TRAPUM (TRansients And PUlsars with MeerKAT) collaboration has performed a radio-domain search for pulsars and transients in the dwarf star-forming galaxies Sextans A and B, situated at the edge of the Local Group 1.4 Mpc away. We conducted three 2-h multibeam observations at L band (856–1712 MHz) with the full array of MeerKAT. No pulsars were found down to a radio pseudo-luminosity upper limit of 7.9 |$\pm$| 0.4 Jy kpc |$^{2}$| at 1400 MHz, which is 28 times more sensitive than the previous limit from the Murriyang telescope. This luminosity is 30 per cent greater than that of the brightest known radio pulsar and sets a cut-off on the luminosity distributions of the entire Sextans A and B galaxies for unobscured radio pulsars beamed in our direction. A fast radio burst was detected in one of the Sextans A observations at a dispersion measure (DM) of 737 pc cm |$^{-3}$|⁠. We believe this is a background event not associated with the dwarf galaxy due to its large DM and its signal-to-noise ratio being strongest in the wide-field incoherent beam of MeerKAT. [ABSTRACT FROM AUTHOR]

Published

2024

23. General relativistic self-gravitating equilibrium discs around rotating neutron stars.

Author

Kim, Yoonsoo, Kim, Jinho, Kim, Hee Il, and Lee, Hyung Mok

Subjects

*SELF-consistent field theory, *NEUTRON stars, *COMPACT discs, *RELATIVISTIC electrons, *HYDRODYNAMICS

Abstract

In modelling a relativistic disc around a compact object, the self-gravity of the disc is often neglected while it needs to be incorporated for more accurate descriptions in several circumstances. Extending the Komatsu–Eriguchi–Hachisu self-consistent field method, we present numerical models of a rapidly rotating neutron star with a self-gravitating disc in stationary equilibrium. In particular, our approach allows us to obtain numerical solutions involving a massive disc with the rest mass |$\mathcal {O}(10^{-1})-\mathcal {O}(10^0)\, \mathrm{ M}_\odot$| closely attached to a rotating neutron star, given that the disc is mainly supported by the relativistic electron degeneracy pressure. We also assess the impact of self-gravity on the internal structure of the disc and the neutron star. These axisymmetric, stationary solutions can be employed for simulations involving the neutron star–disc system in the context of high-energy transients and gravitational-wave emissions. [ABSTRACT FROM AUTHOR]

Published

2024

24. Comprehensive investigations on spectral and temporal features of GX 5−1 using AstroSat observations.

Author

Thomas, Neal Titus, Giridharan, L, Gudennavar, S B, and Bubbly, S G

Subjects

*MAGNETIC dipole moments, *X-ray binaries, *NEUTRON stars, *X-ray telescopes, *ACCRETION disks

Abstract

Comprehensive spectrotemporal analyses of the Z-type neutron star low-mass X-ray binary GX 5−1 were performed using 10 broad-band observations from AstroSat /Soft X-ray Telescope and Large Area X-ray Proportional Counter (LAXPC) instruments. The LAXPC-20 hardness–intensity diagram showed horizontal and normal branches (HBs and NBs) of the Z track which exhibited secular motion. The time-averaged spectra in the energy range 0.7–25.0 keV could be fitted with the model combination – |$\tt {constant}\, \times \, \tt {tbabs}\, \times \, \tt {edge}\, \times \, \tt {edge}\, \times \, \tt {thcomp}\, \times \, \tt {diskbb}$|⁠. This yielded |$\Gamma \, \sim$| 2, |$kT_{\mathrm{ e}}\, \sim$| 3.3 keV, and |$F_{\mathrm{ disc}}$| / |$F_{\mathrm{ total}}\, \sim$| 0.8 indicating the soft/intermediate spectral state of the source during the observations. Flux-resolved spectral analysis revealed a positive correlation between |$kT_{\mathrm{ in}}$| and |$F_{\mathrm{ bol}}$|⁠. However, a negative correlation was observed between them in one of the NBs. Time-averaged temporal analysis revealed multiple HB oscillations (HBOs) and NB oscillations (NBOs), and peaked noise components in the |$\sim$| 5–50 Hz range. Furthermore, flux-resolved temporal analysis showed that the frequency of the HBOs correlates positively whereas the strength of HBOs correlates negatively with |$F_{\mathrm{ bol}}$|⁠ , indicating their probable origin from the accretion disc. In contrast, the frequency and strength of NBOs remain fairly constant with |$F_{\mathrm{ bol}}$|⁠ , suggesting that they originate from a different region in the system. Using the relativistic precession model along with highest frequency of the HBO, the upper limits of the magnetic dipole moment (⁠|$\mu$|⁠) and field strength (B) at the poles of the neutron star in the system were found to be 25.60 |$\times \, 10^{25}$| G cm3 and 3.64 |$\times \, 10^{8}$| G, respectively, for |$k_{\mathrm{ A}}$| = 1. [ABSTRACT FROM AUTHOR]

Published

2024

25. Spectral and timing properties of the accreting millisecond X-ray pulsar IGR J17498−2921 during its 2023 outburst.

Author

Illiano, G., Papitto, A., Marino, A., Strohmayer, T. E., Sanna, A., Di Salvo, T., La Placa, R., Ambrosino, F., Miraval Zanon, A., Coti Zelati, F., Ballocco, C., Malacaria, C., Ghedina, A., Cecconi, M., Gonzales, M., and Leone, F.

Subjects

*ELECTRON emission, *X-ray binaries, *NEUTRON stars, *ELECTRON temperature, *ACCRETION disks

Abstract

We present a comprehensive study of the spectral properties of the accreting millisecond X-ray pulsar IGR J17498−2921 during its 2023 outburst. Similar to other accreting millisecond X-ray pulsars, the broadband spectral emission observed quasi-simultaneously by NICER and NuSTAR is well described by an absorbed Comptonized emission with an electron temperature of ∼17 keV plus a disk reflection component. The broadening of the disk reflection spectral features, such as a prominent iron emission line at 6.4–6.7 keV, is consistent with the relativistic motion of matter in a disk truncated at ∼21 Rg from the source, near the Keplerian corotation radius. From the high-cadence monitoring data obtained with NICER, we observed that the evolution of the photon index and the temperature of seed photons tracks variations in the X-ray flux. This is particularly evident close to a sudden ∼–0.25 cycle jump in the pulse phase, which occurs immediately following an X-ray flux flare and a drop in the pulse amplitude below the 3σ detection threshold. We also report on the non-detection of optical pulsations with TNG/SiFAP2 from the highly absorbed optical counterpart. [ABSTRACT FROM AUTHOR]

Published

2024

26. Stable case BB/BC mass transfer to form GW190425-like massive binary neutron star mergers.

Author

Qin, Ying, Zhu, Jin-Ping, Meynet, Georges, Zhang, Bing, Wang, Fa-Yin, Shu, Xin-Wen, Song, Han-Feng, Wang, Yuan-Zhu, Yuan, Liang, Wang, Zhen-Han-Tao, Hu, Rui-Chong, Wu, Dong-Hong, Yi, Shuang-Xi, Tang, Qing-Wen, Wei, Jun-Jie, Wu, Xue-Feng, and Liang, En-Wei

Subjects

*STELLAR structure, *STELLAR mass, *NEUTRON stars, *STELLAR mergers, *STARS

Abstract

Context. On April 25, 2019, the LIGO-Virgo Collaboration discovered a gravitational-wave (GW) signal from a binary neutron star (BNS) merger, that is, GW190425. Due to the inferred large total mass, the origin of GW190425 remains unclear. Aims. Assuming GW190425 originated from the standard isolated binary evolution channel, its immediate progenitor is considered to be a close binary system, consisting of a He-rich star and a NS just after the common envelope phase. We aim to study the formation of GW190425 in a solar-like environment by using the detailed binary evolution code MESA. Methods. We perform detailed stellar structure and binary evolution calculations that take into account mass loss, internal differential rotation, and tidal interactions between a He-rich star and a NS companion. We explore the parameter space of the initial binary properties, including initial NS and He-rich masses and initial orbital period. Results. We find that the immediate post-common-envelope progenitor system, consisting of a primary ∼2.0 M⊙ (∼1.7 M⊙) NS and a secondary He-rich star with an initial mass of ∼3.0 − 5.5 M⊙ (∼5.5 − 6.0 M⊙) in a close binary with an initial period of ∼0.08 − 0.5 days (∼0.08 − 0.4 days), that experiences stable Case BB/BC mass transfer (MT) during binary evolution, can reproduce the formation of GW190425-like BNS events. Our studies reveal that the secondary He-rich star of the GW190425's progenitor before its core collapse can be efficiently spun up through tidal interaction, finally remaining as a NS with rotational energy even reaching ∼1052 erg, which is always much higher than the neutrino-driven energy of the supernova (SN) explosion. If the newborn secondary NS is a magnetar, we expect that GW190425 can be the remnant of a magnetar-driven SN, namely a magnetar-driven ultra-stripped SN, a superluminous SN, or a broad-line Type Ic SN. Conclusions. Our results show that GW190425 could be formed through the isolated binary evolution, which involves a stable Case BB/BC MT just after the common envelope phase. On top of that, we show the He-rich star can be tidally spun up, potentially forming a spinning magnetized NS (magnetar) during the second SN explosion. [ABSTRACT FROM AUTHOR]

Published

2024

27. Broadband X-ray spectral and timing properties of the accreting millisecond X-ray pulsar IGR J17498−2921 during the 2023 outburst.

Author

Li, Z. S., Kuiper, L., Pan, Y. Y., Falanga, M., Poutanen, J., Chen, Y. P., Xu, R. X., Ge, M. Y., Huang, Y., Song, L. M., Zhang, S., Lu, F. J., and Zhang, S. N.

Subjects

*X-ray bursts, *NEUTRON stars, *ACCRETION disks, *ELECTRON temperature, *MAGNETIC fields

Abstract

We report on the broadband spectral and timing properties of the accreting millisecond X-ray pulsar IGR J17498−2921 during its April 2023 outburst. We used data from NICER (1–10 keV), NuSTAR (3–79 keV), Insight-HXMT (2–150 keV), and INTEGRAL (30–150 keV). We detected significant 401 Hz pulsations across the 0.5–150 keV band. The pulse fraction increases from ∼2% at 1 keV to ∼13% at 66 keV. We detected five type-I X-ray bursts, including three photospheric radius expansion bursts, with a rise time of ∼2 s and an exponential decay time of ∼5 s. The recurrence time is ∼9.1 h, which can be explained by unstable thermonuclear burning of hydrogen-deficient material on the neutron star surface. The quasi-simultaneous 1–150 keV broadband spectra from NICER, NuSTAR and INTEGRAL can be aptly fitted by an absorbed reflection model, relxillCp, and a Gaussian line of instrumental origin. The Comptonized emission from the hot corona is characterized by a photon index Γ of ∼1.8 and an electron temperature kTe of ∼40 keV. We obtained a low inclination angle i ∼ 34°. The accretion disk shows properties of strong ionization, log(ξ/erg cm s−1)∼4.5, over-solar abundance, AFe ∼ 7.7, and high density, log(ne/cm−3)∼19.5. However, a lower disk density with normal abundance and ionization could also be possible. Based on the inner disk radius of Rin = 1.67RISCO and the long-term spin-down rate of −3.1(2)×10−15 Hz s−1, we were able to constrain the magnetic field of IGR J17498−2921 to the range of (0.9 − 2.4)×108 G. [ABSTRACT FROM AUTHOR]

Published

2024

28. The high-energy cyclotron line in 2S 1417-624 discovered with Insight-HXMT during the 2018 outburst.

Author

Liu, Q., Santangelo, A., Kong, L. D., Ducci, L., Ji, L., Wang, W., Serim, M. M., Güngör, C., Tuo, Y. L., and Serim, D.

Subjects

*STELLAR magnetic fields, *BINARY pulsars, *X-ray binaries, *NEUTRON stars, *CYCLOTRONS

Abstract

We report a detailed timing and spectral analysis of the X-ray pulsar 2S 1417−624 using the data from Insight-HXMT during the 2018 outburst. The pulse profiles are highly variable with respect to both unabsorbed flux and energy. A double-peaked pulse profile from the low flux evolved to a multi-peaked shape in the high-flux state. The pulse fraction is negatively correlated to the source flux in the range of ∼(1 − 6)×10−9 erg cm−2 s−1, consistent with Rossi X-ray Timing Explorer (RXTE) studies during the 2009 giant outburst. The energy-resolved pulse profiles around the peak outburst showed a four-peak shape in the low-energy bands and gradually evolved to triple peaks at higher energies. The continuum spectrum is well described by typical phenomenological models, such as the cut-off power law and the power law with high-energy cut-off models. Notably, we discovered high-energy cyclotron resonant scattering features (CRSFs) for the first time, which are around 100 keV with a statistical significance of ∼7σ near the peak luminosity of the outburst. This CRSF line is significantly detected with different continuum models and provides very robust evidence for its presence. Furthermore, pulse-phase-resolved spectroscopy confirmed the presence of the line, whose energy varied from 97 to 107 keV over the pulse phase and appeared to have a maximum value at the narrow peak phase of the profiles. [ABSTRACT FROM AUTHOR]

Published

2024

29. X-ray and optical observations of the millisecond pulsar binary PSR J1431–4715.

Author

de Martino, D., Phosrisom, A., Dhillon, V. S., Torres, D. F., Coti Zelati, F., Breton, R. P., Marsh, T. R., Miraval Zanon, A., Rea, N., and Papitto, A.

Subjects

*SYNCHROTRON radiation, *STELLAR winds, *NEUTRON stars, *X-ray spectra, *LIGHT curves, *BINARY pulsars

Abstract

We present the first X-ray observation of the energetic millisecond pulsar binary PSR J1431−4715, performed with XMM-Newton and complemented with fast optical multi-band photometry acquired with the ULTRACAM instrument at ESO-NTT. It is found as a faint X-ray source without a significant orbital modulation. This contrasts with the majority of systems that instead display substantial X-ray orbital variability. The X-ray spectrum is dominated by non-thermal emission and, due to the lack of orbital modulation, does not favour an origin in an intrabinary shock between the pulsar and companion star wind. While thermal emission from the neutron star polar cap cannot be excluded in the soft X-rays, the dominance of synchrotron emission favours an origin in the pulsar magnetosphere that we describe at both X-ray and gamma-ray energies with a synchro-curvature model. The optical multi-colour light curve folded at the 10.8 h orbital period is double-humped and dominated by ellipsoidal effects, but also affected by irradiation. The ULTRACAM light curves are fit with several models encompassing direct heating and a cold spot, or heat redistribution after irradiation either through convection or convection plus diffusion. Despite the inability to constrain the best irradiation models, the fits provide consistent system parameters, giving an orbital inclination of 59 ± 6° and a distance of 3.1 ± 0.3 kpc. The companion is found to be an F-type star, underfilling its Roche lobe (fRL = 73 ± 4%) with a mass of 0.20 ± 0.04 M⊙, confirming the redback status, but hotter than the majority of redbacks. The stellar dayside and nightside temperatures of 7500 K and 7400 K, respectively, indicate a weak irradiation effect on the companion, likely due to its high intrinsic luminosity. Although the pulsar mass cannot be precisely derived, a heavy (1.8−2.2 M⊙) neutron star is favoured. [ABSTRACT FROM AUTHOR]

Published

2024

30. Poynting flux transport channels formed in polar cap regions of neutron star magnetospheres.

Author

Benáček, Jan, Timokhin, Andrey, Muñoz, Patricio A., Jessner, Axel, Rievajová, Tatiana, Pohl, Martin, and Büchner, Jörg

Subjects

*NEUTRON stars, *RADIO waves, *COHERENT radiation, *ELECTROMAGNETIC waves, *PLASMA flow

Abstract

Context. Pair cascades in polar cap regions of neutron stars are considered to be an essential process in various models of coherent radio emissions of pulsars. The cascades produce pair plasma bunch discharges in quasi-periodic spark events. The cascade properties, and therefore also the coherent radiation, depend strongly on the magnetospheric plasma properties and vary significantly across and along the polar cap. Importantly, where the radio emission emanates from in the polar cap region is still uncertain. Aims. We investigate the generation of electromagnetic waves by pair cascades and their propagation in the polar cap for three representative inclination angles of a magnetic dipole, 0°, 45°, and 90°. Methods. We use two-dimensional particle-in-cell simulations that include quantum-electrodynamic pair cascades in a charge-limited flow from the star surface. Results. We find that the discharge properties are strongly dependent on the magnetospheric current profile in the polar cap and that transport channels for high intensity Poynting flux are formed along magnetic field lines where the magnetospheric currents approach zero and where the plasma cannot carry the magnetospheric currents. There, the parallel Poynting flux component is efficiently transported away from the star and may eventually escape the magnetosphere as coherent radio waves. The Poynting flux decreases with increasing distance from the star in regions of high magnetospheric currents. Conclusions. Our model shows that no process of energy conversion from particles to waves is necessary for the coherent radio wave emission. Moreover, the pulsar radio beam does not have a cone structure; rather, the radiation generated by the oscillating electric gap fields directly escapes along open magnetic field lines in which no pair creation occurs. [ABSTRACT FROM AUTHOR]

Published

2024

31. Probing the polarized emission from SMC X-1: The brightest X-ray pulsar observed by IXPE.

Author

Forsblom, Sofia V., Tsygankov, Sergey S., Poutanen, Juri, Doroshenko, Victor, Mushtukov, Alexander A., Ng, Mason, Ravi, Swati, Marshall, Herman L., Di Marco, Alessandro, La Monaca, Fabio, Malacaria, Christian, Mastroserio, Guglielmo, Loktev, Vladislav, Possenti, Andrea, Suleimanov, Valery F., Taverna, Roberto, Agudo, Iván, Antonelli, Lucio A., Bachetti, Matteo, and Baldini, Luca

Subjects

*ACCRETION disks, *NEUTRON stars, *BREWSTER'S angle, *X-ray binaries, *X-ray imaging

Abstract

Recent observations of X-ray pulsars (XRPs) performed by the Imaging X-ray Polarimetry Explorer (IXPE) have made it possible to investigate the intricate details of these objects in a new way, thanks to the added value of X-ray polarimetry. Here we present the results of the IXPE observations of SMC X-1, a member of the small group of XRPs displaying super-orbital variability. SMC X-1 was observed by IXPE three separate times during the high state of its super-orbital period. The observed luminosity in the 2–8 keV energy band of L ∼ 2 × 1038 erg s−1 makes SMC X-1 the brightest XRP ever observed by IXPE. We detect significant polarization in all three observations, with values of the phase-averaged polarization degree (PD) and polarization angle (PA) of 3.2 ± 0.8% and 97° ±8° for Observation 1, 3.0 ± 0.9% and 90° ±8° for Observation 2, and 5.5 ± 1.1% and 80° ±6° for Observation 3, for the spectro-polarimetric analysis. The observed PD shows an increase over time with decreasing luminosity, while the PA decreases in decrements of ∼10°. The phase-resolved spectro-polarimetric analysis reveals significant detection of polarization in three out of seven phase bins, with the PD ranging between ∼2% and ∼10%, and a corresponding range in the PA from ∼70° to ∼100°. The pulse-phase resolved PD displays an apparent anti-correlation with the flux. Using the rotating vector model, we obtain constraints on the pulsar's geometrical properties for the individual observations. The position angle of the pulsar displays an evolution over time supporting the idea that we observe changes related to different super-orbital phases. Scattering in the wind of the precessing accretion disk may be responsible for the behavior of the polarimetric properties observed during the high-state of SMC X-1's super-orbital period. [ABSTRACT FROM AUTHOR]

Published

2024

32. Studying geometry of the ultraluminous X-ray pulsar Swift J0243.6+6124 using X-ray and optical polarimetry.

Author

Poutanen, Juri, Tsygankov, Sergey S., Doroshenko, Victor, Forsblom, Sofia V., Jenke, Peter, Kaaret, Philip, Berdyugin, Andrei V., Blinov, Dmitry, Kravtsov, Vadim, Liodakis, Ioannis, Tzouvanou, Anastasia, Di Marco, Alessandro, Heyl, Jeremy, La Monaca, Fabio, Mushtukov, Alexander A., Pavlov, George G., Salganik, Alexander, Veledina, Alexandra, Weisskopf, Martin C., and Zane, Silvia

Subjects

*ANGULAR momentum (Mechanics), *NEUTRON stars, *EDDINGTON mass limit, *OPTICAL measurements, *BREWSTER'S angle

Abstract

Discovery of pulsations from a number of ultra-luminous X-ray (ULX) sources proved that accretion onto neutron stars can produce luminosities exceeding the Eddington limit by several orders of magnitude. The conditions necessary to achieve such high luminosities as well as the exact geometry of the accretion flow in the neutron star vicinity are, however, a matter of debate. The pulse phase-resolved polarization measurements that became possible with the launch of the Imaging X-ray Polarimetry Explorer (IXPE) can be used to determine the pulsar geometry and its orientation relative to the orbital plane. They provide an avenue to test different theoretical models of ULX pulsars. In this paper we present the results of three IXPE observations of the first Galactic ULX pulsar Swift J0243.6+6124 during its 2023 outburst. We find strong variations in the polarization characteristics with the pulsar phase. The average polarization degree increases from about 5% to 15% as the flux dropped by a factor of three in the course of the outburst. The polarization angle (PA) as a function of the pulsar phase shows two peaks in the first two observations, but changes to a characteristic sawtooth pattern in the remaining data set. This is not consistent with a simple rotating vector model. Assuming the existence of an additional constant polarized component, we were able to fit the three observations with a common rotating vector model and obtain constraints on the pulsar geometry. In particular, we find the pulsar angular momentum inclination with respect to the line of sight of ip = 15°–40°, the magnetic obliquity of θp = 60°–80°, and the pulsar spin position angle of χp ≈ −50°, which significantly differs from the constant component PA of about 10°. Combining these X-ray measurements with the optical PA, we find evidence for at least a 30° misalignment between the pulsar angular momentum and the binary orbital axis. [ABSTRACT FROM AUTHOR]

Published

2024

33. Radiation mechanism of twin kilohertz quasi-periodic oscillations in neutron star low-mass X-ray binaries.

Author

Shi, Chang-Sheng, Zhang, Guo-Bao, Zhang, Shuang-Nan, and Li, Xiang-Dong

Subjects

*MARKOV chain Monte Carlo, *X-ray binaries, *COMPACT objects (Astronomy), *NEUTRON scattering, *ELECTRON temperature

Abstract

Context. The connection between quasi-periodic oscillations (QPOs) and magnetic fields has been investigated in various celestial bodies. Magnetohydrodynamic (MHD) waves have been employed to explain the simultaneous upper and lower kilohertz (kHz) QPOs. Nevertheless, the intricate and undefined formation pathways of twin kHz QPOs present a compelling avenue for exploration. This study area holds great interest as it provides an opportunity for deriving crucial parameters related to compact stars. Aims. We strive to develop a self-consistent model elucidating the radiation mechanism of twin kHz QPOs, which we then compare it with observations. Methods. A sample of 28 twin kHz QPOs detected from the X-ray binary 4U 1636–53 was used for a comparison with the results of the Markov chain Monte Carlo calculations based on our model of the radiation mechanism of twin kHz QPOs, which is related to twin MHD waves. Results. We obtained 28 groups of parameters of 4U 1636–53 and a tight exponential fit between the flux and the temperature of seed photons to Compton up-scattering and find that the electron temperature in the corona around the neutron star decreases with increasing seed photon temperature. Conclusions. The origin of twin kHz QPOs are dual disturbances that arise from twin MHD waves that are generated at the innermost radius of an accretion disc. The seed photons can be transported through a high temperature corona and are Compton up-scattered. The photons that vary the frequencies of twin MHD waves lead to the observed twin kHz QPOs. [ABSTRACT FROM AUTHOR]

Published

2024

34. Accretion tori around rotating neutron stars: II. Oscillations and precessions.

Author

Matuszková, Monika, Török, Gabriel, Klimovičová, Kateřina, Horák, Jiří, Straub, Odele, Šrámková, Eva, Lančová, Debora, Urbanec, Martin, Urbancová, Gabriela, and Karas, Vladimír

Subjects

*FREQUENCIES of oscillating systems, *NEUTRON stars, *X-ray binaries, *BLACK holes, *QUADRUPOLE moments

Abstract

The four characteristic oscillation frequencies of accretion flows (in addition to the Keplerian orbital frequency) are often discussed in the context of the time variability of black hole and neutron star (NS) low-mass X-ray binaries (LMXBs). These four frequencies are the frequencies of the axisymmetric radial and vertical epicyclic oscillations, and the frequencies of non-axisymmetric oscillations corresponding to the periastron (radial) and Lense-Thirring (vertical) precessions. In this context, we investigated the effect of the quadrupole moment of a slowly rotating NS and provide complete formulae for calculating these oscillation and precession frequencies, as well as convenient approximations. Simple formulae corresponding to the geodesic limit of a slender torus (and test-particle motion) and the limit of a marginally overflowing torus (a torus exhibiting a critical cusp) are presented, and more general approximate formulae are included to allow calculations for arbitrarily thick tori. We provide the Wolfram Mathematica code used for our calculations together with the C++ and PYTHON codes for calculating the frequencies. Our formulae can be used for various calculations regarding the astrophysical signatures of the NS super-dense matter equation of state. For instance, we demonstrate that even for a given fixed number of free parameters, a model that accounts for fluid flow precession matches the frequencies of twin-peak quasiperiodic oscillations observed in NS LMXBs better than a model that uses geodesic precession. [ABSTRACT FROM AUTHOR]

Published

2024

35. Accretion tori around rotating neutron stars: I. Structure, shape, and size.

Author

Matuszková, Monika, Török, Gabriel, Lančová, Debora, Klimovičová, Kateřina, Horák, Jiří, Urbanec, Martin, Šrámková, Eva, Straub, Odele, Urbancová, Gabriela, and Karas, Vladimír

Subjects

*ANGULAR momentum (Mechanics), *NEUTRON stars, *QUADRUPOLE moments, *ACCRETION disks, *TORUS

Abstract

We present a full general relativistic analytic solution for a radiation-pressure-supported equilibrium fluid torus orbiting a rotating neutron star (NS). We applied previously developed analytical methods that include the effects of both the NS's angular momentum and quadrupole moment in the Hartle-Thorne geometry. The structure, size, and shape of the torus are explored, with a particular focus on the critically thick solution – the cusp tori. For the astrophysically relevant range of NS parameters, we examined how our findings differ from those obtained for the Schwarzschild space-time. The solutions for rotating stars display signatures of an interplay between relativistic and Newtonian effects where the impact of the NS angular momentum and quadrupole moment are almost counterbalanced at a given radius. Nevertheless, the space-time parameters still strongly influence the size of tori, which can be shown in a coordinate-independent way. Finally, we discuss the importance of the size of the central NS which determines whether or not a surrounding torus exists. We provide a set of tools in a Wolfram Mathematica code, which establishes a basis for further investigation of the impact of the NSs' super-dense matter equation of state on the spectral and temporal behaviour of accretion tori. [ABSTRACT FROM AUTHOR]

Published

2024

36. Triple trouble with PSR J1618−3921: Mass measurements and orbital dynamics of an eccentric millisecond pulsar.

Author

Grunthal, K., Venkatraman Krishnan, V., Freire, P. C. C., Kramer, M., Bailes, M., Buchner, S., Burgay, M., Cameron, A. D., Chen, C.-H.R., Cognard, I., Guillemot, L., Lower, M. E., Possenti, A., and Theureau, G.

Subjects

*TRIPLE stars, *RADIO telescopes, *GENERAL relativity (Physics), *NEUTRON stars, *MASS measurement

Abstract

Context. PSR J1618−3921 is one of five known millisecond pulsars (MSPs) in eccentric orbits (eMPSs) located in the Galactic plane, whose formation is poorly understood. Earlier studies of these objects revealed significant discrepancies between observations and predictions from standard binary evolution scenarios of pulsar-helium white dwarf (HeWD) binaries, especially in the case of PSR J0955−6150, for which mass measurements ruled out most eMSP formation models. Aims. We aim to measure the masses of the pulsar and its companion, and constrain the orbital configuration of PSR J1618−3921. This facilitates understanding similarities among eMSPs and could offer hints as to their formation mechanism. Methods. We conducted observations with the L-band receiver of the MeerKAT radio telescope and the UWL receiver of the Parkes Murriyang radio telescope between 2019 and 2021. These data were added to archival Parkes and Nançay observations. We performed a full analysis on this joint data set with a timing baseline of 23 years. We also used the data from recent observations to give a brief account of the emission properties of J1618−3921, including a rotating vector model (RVM) fit of the linear polarisation position angle of the pulsar. Results. From the timing analysis, we measure a small but significant proper motion of the pulsar. The long timing baseline allowed for a highly significant measurement of the rate of advance of periastron of ω̇ = (0.00145±0.00010)°yr−1. Despite the tenfold improvement in timing precision from MeerKAT observations, we can only report a low-significance detection of the orthometric Shapiro delay parameters, h3 = 2.70−1.47+2.07 μs and ς = 0.68−0.09+0.13. Under the assumption of the validity of general relativity (GR), the self-consistent combination of these three parameters leads to mass estimates of the total and individual masses in the binary of Mtot = 1.42−0.19+0.20 M⊙, Mc = 0.20−0.03+0.11 M⊙, and Mp = 1.20−0.20+0.19 M⊙. We detect an unexpected change in the orbital period of Ṗb = −2.26−0.33+0.35 × 10−12, that is an order of magnitude larger and carries an opposite sign to what is expected from the Galactic acceleration and the Shklovskii effect, which are a priori the only non-negligible contributions expected for Ṗb. We also detect a significant second derivative of the spin frequency, f̈. The RVM fit reveals a viewing angle of ζ = (111 ± 1)°. Furthermore, we report an unexpected, abrupt change in the mean pulse profile in June 2021 of unknown origin. Conclusions. We propose that the anomalous Ṗb and f̈ we measure for J1618−3921 indicate an additional varying acceleration due to a nearby mass. The J1618−3921 binary system is likely part of a hierarchical triple, but with the third component much farther away than the outer component of the MSP in a triple star system, PSR J0337+1715. This finding suggests that at least some eMSPs might have formed in triple star systems. Although the uncertainties are large, the binary companion mass is consistent with the Pb − MWD relation, which has been verified for circular HeWD binaries and also for the two HeWDs in the PSR J0337+1715 system. Future regular observations with the MeerKAT telescope will, due to the further extension of the timing baseline, improve the measurement of Ṗb and f̈. This will help us further understand the nature of this system, and perhaps improve our understanding of eMSPs in general. [ABSTRACT FROM AUTHOR]

Published

2024

37. Indication of rapid magnetic field decay in X-ray dim isolated neutron star RX J0720.4−3125.

Author

Igoshev, Andrei P and Popov, Sergei B

Subjects

*NEUTRON stars, *MAGNETIC fields, *ENERGY dissipation, *STELLAR evolution, *EMISSION standards, *STELLAR magnetic fields

Abstract

Magnetic field evolution of neutron stars is a long-standing debate. The rate of magnetic field decay for isolated, non-accreting neutron stars can be quantified by measuring the negative second derivative of the spin period. Alternatively, this rate can be estimated by observing an excess of thermal emission with respect to the standard cooling without additional heating mechanisms involved. One of the nearby cooling isolated neutron stars – RX J0720.4−3125, – offers a unique opportunity to probe the field decay as for this source there are independent measurements of the surface X-ray luminosity, the second spin period derivative, and magnetic field. We demonstrate that the evolution rate of the spin period derivative is in correspondence with the rate of dissipation of magnetic energy of the dipolar field if a significant part of the released energy is emitted in X-rays. The instantaneous time-scale for the magnetic field decay is |${\sim} 10^4$|  yr. [ABSTRACT FROM AUTHOR]

Published

2024

38. AstroSat's view of 4U 1735−44: spectral, temporal, and type I X-ray burst studies.

Author

Lavanya, S, Thomas, Neal Titus, Gudennavar, S B, and Bubbly, S G

Subjects

*X-ray bursts, *X-ray binaries, *X-ray telescopes, *ACCRETION disks, *NEUTRON stars

Abstract

This study utilizes the simultaneous broad-band observations of 4U 1735−44 from AstroSat , offering enhanced spectral and temporal resolution, to investigate its spectral properties, temporal behaviour, and burst characteristics. Spectral, type I X-ray burst, and temporal analyses on 4U 1735−44 were performed using AstroSat /Soft X-ray Telescope and Large Area X-ray Proportional Counter (LAXPC) observations. The hardness–intensity diagram from LAXPC-20 showed a positive correlation between hardness and intensity, with a pattern resembling the banana branch typical of atoll sources. Spectral analysis carried out in the 0.7–20.0 keV energy range, using the model combination – |$\tt {constant}$| |$\times$| |$\tt {tbabs}$| (⁠|$\tt {nthcomp}$| |$+$| |$\tt {diskbb}$| |$+$| |$\tt {bbodyrad}$|⁠), suggested a cool accretion disc truncated at a large distance from the neutron star in the system. Time-resolved spectral studies of two type I X-ray bursts detected from the source revealed evidence of photospheric radius expansion, allowing for an estimation of the source distance. Temporal analysis showed the presence of low-frequency quasi-periodic oscillation at |$\sim$| 69 Hz (3.3 |$\sigma$| significance with more than 99 per cent confidence) and prominent noise features below 30 Hz. [ABSTRACT FROM AUTHOR]

Published

2024

39. Signatures of low-mass black hole–neutron star mergers.

Author

Matur, Rahime, Hawke, Ian, and Andersson, Nils

Subjects

*BLACK holes, *STELLAR mergers, *PROPERTIES of matter, *NEUTRON stars, *PHASES of matter, *GRAVITATIONAL waves

Abstract

The recent observation of the GW230529 event indicates that black hole–neutron star binaries can contain low-mass black holes. Since lower mass systems are more favourable for tidal disruption, such events are promising candidates for multimessenger observations. In this study, we employ five finite-temperature, composition-dependent matter equations of state and present results from ten 3D general relativistic hydrodynamic simulations for the mass ratios |$q = 2.6$| and 5. Two of these simulations target the chirp mass and effective spin parameter of the GW230529 event, while the remaining eight contain slightly higher mass black holes, including both spinning (⁠|$a_{\mathrm{ BH}} = 0.7$|⁠) and non-spinning (⁠|$a_{\mathrm{ BH}} = 0$|⁠) models. We discuss the impact of the equation of state, spin, and mass ratio on black hole–neutron star mergers by examining both gravitational-wave and ejected matter properties. For the low-mass ratio model we do not see fast-moving ejecta for the softest equation of state model, but the stiffer model produces on the order of |$10^{-6}\,\mathrm{ M}_\odot$| of fast-moving ejecta, expected to contribute to an electromagnetic counterpart. Notably, the high-mass ratio model produces nearly the same amount of total dynamical ejecta, but yields 52 times more fast-moving ejecta than the low-mass ratio system. In addition, we observe that the black-hole spin tends to decrease the amount of fast-moving ejecta while increasing significantly the total ejected mass. Finally, we note that the disc mass tends to increase as the neutron star compactness decreases. [ABSTRACT FROM AUTHOR]

Published

2024

40. Long-term evolutionary links between the isolated neutron star populations.

Author

Gençali, A A and Ertan, Ü

Subjects

*STELLAR populations, *NEUTRON stars, *BIRTH rate, *ACCRETION disks, *DIPOLE moments

Abstract

We have investigated the evolutionary connections of the isolated neutron star (NS) populations including radio pulsars (RPs), anomalous X-ray pulsars (AXPs), soft gamma repeaters (SGRs), dim isolated NSs (XDINs), 'high-magnetic field' RPs ('HBRPs'), central compact objects (CCOs), rotating radio transients (RRATs), and long-period pulsars (LPPs) in the fallback disc model. The model can reproduce these NS families as a natural outcome of different initial conditions (initial period, disc mass, and dipole moment, μ) with a continuous μ distribution in the |$\sim 10^{27} - 5 \times 10^{30}$| G cm |$^3$| range. Results of our simulations can be summarized as follows: (1) A fraction of 'HBRPs' with relatively high μ evolve into the persistent AXP/SGR properties, and subsequently become LPPs. (2) Persistent AXP/SGRs do not have evolutionary links with CCOs, XDINs, and RRATs. (3) For a wide range of μ , most RRATs evolve passing through RP or 'HBRP' properties during their early evolutionary phases. (4) A fraction of RRATs which have the highest estimated birth rate seem to be the progenitors of XDINs. (5) LPPs, whose existence was predicted by the fallback disc model, are the sources evolving in the late stage of evolution before the discs become inactive. These results provide concrete support to the ideas proposing evolutionary connections between the NS families to account for the 'birth rate problem', the discrepancy between the cumulative birth rate estimated for these systems and the core-collapse supernova rate. [ABSTRACT FROM AUTHOR]

Published

2024

41. 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

42. Correction to: Searching for magnetar binaries disrupted by core-collapse supernovae.

Author

Sherman, Myles B, Ravi, Vikram, El-Badry, Kareem, Sharma, Kritti, Ocker, Stella Koch, Kosogorov, Nikita, Connor, Liam, and Faber, Jakob T

Subjects

*SUPERGIANT stars, *SUPERNOVA remnants, *NEUTRON stars, *MONTE Carlo method, *ANGULAR distance, *MAGNETARS

Published

2024

43. The 2021 outburst of 2S 1417–624 revisited with AstroSat.

Author

Jain, Chetana

Subjects

*X-ray binaries, *ACCRETION disks, *PULSARS, *NEUTRONS

Abstract

This work presents the first-ever broadband (0.7–25.0 keV) timing and spectral analysis of Be-HMXB 2S 1417–624 during its 2021 outburst. Using AstroSat observations, coherent pulsations at ∼ 17.36633 s (MJD 59239.082) were detected in 0.7–7.0 keV SXT and 3.0–25.0 keV LAXPC data. The pulse profile was dual peaked at all energies, with the relative intensity of the main peak increasing with energy. The peaks in the SXT profiles were broad and comprised of several mini-structures. The LAXPC profiles were relatively smooth and had higher pulsed fractions, which increased with energy. The SXT + LAXPC simultaneous energy spectrum is well described by an absorbed power-law with exponential cut-off, a ∼ 1.6 keV black body component, and a 6.47 keV emission line. A model comprising of an absorbed power law with high energy cut-off plus a partial covering absorber and Gaussian emission line fits the spectrum quite well. These results have been compared with timing and spectral features during the previous outbursts of this transient pulsar. [ABSTRACT FROM AUTHOR]

Published

2024

44. Relativistic X-ray reflection from the accreting millisecond X-ray pulsar IGR J17498−2921.

Author

Bhattacharya, Mahasweta, Mondal, Aditya S, Pahari, Mayukh, Raychaudhuri, Biplab, Ghosh, Rohit, and Dewangan, Gulab C

Subjects

*X-ray bursts, *MAGNETIC flux density, *X-ray spectra, *X-ray reflection, *ACCRETION disks

Abstract

The accreting millisecond X-ray pulsar IGR J17498−2921 went into X-ray outburst on 2023 April 13–15, for the first time since its discovery on 2011 August 11. Here, we report on the first follow-up NuSTAR observation of the source, performed on 2023 April 23, around 10 d after the peak of the outburst. The NuSTAR spectrum of the persistent emission (3–60 keV band) is well described by an absorbed blackbody with a temperature of |$kT_{\mathrm{ bb}}=1.61\pm 0.04$|  keV, most likely arising from the NS surface and a Comptonization component with power-law index |$\Gamma =1.79\pm 0.02$|⁠ , arising from a hot corona at |$kT_{e}=16\pm 2$| keV. The X-ray spectrum of the source shows robust reflection features which have not been observed before. We use a couple of self-consistent reflection models, relxill and relxillCp , to fit the reflection features. We find an upper limit to the inner disc radius of |$6\: R_{\mathrm{ ISCO}}$| and |$9\: R_{\mathrm{ ISCO}}$| from relxill and relxillCp model, respectively. The inclination of the system is estimated to be |$\simeq 40^{\circ }$| from both reflection models. Assuming magnetic truncation of the accretion disc, the upper limit of magnetic field strength at the pole of the NS is found to be |$B\lesssim 1.8\times 10^{8}$| G. Furthermore, the NuSTAR observation revealed two type-I X-ray bursts and the burst spectroscopy confirms the thermonuclear nature of the burst. The blackbody temperature reaches nearly 2.2 keV at the peak of the burst. [ABSTRACT FROM AUTHOR]

Published

2024

45. Exploring the case for hard-X-ray beaming in NGC 6946 X-1.

Author

Beuchert, Tobias, Middleton, Matthew J, Soria, Roberto, Miller-Jones, James C A, Dauser, Thomas, Roberts, Timothy P, Sathyaprakash, Rajath, and Markoff, Sera

Subjects

*HARD X-rays, *SOFT X rays, *X-ray binaries, *BLACK holes, *ACCRETION disks

Abstract

In order to understand the nature of super-Eddington accretion we must explore both the emission emerging directly from the inflow and its impact on the surroundings. In this paper, we test whether we can use the optical line emission of spatially resolved, ionized nebulae around ultraluminous X-ray sources (ULXs) as a proxy for their X-ray luminosity. We choose the ULX NGC 6946 X-1 and its nebula, MF16, as a test case. By studying how the nebular optical line emission responds to assumed irradiation, we can infer the degree to which we require the UV or X-ray emission from the inflow to be collimated by optically thick winds seemingly ubiquitously associated with ULXs. We find that the nebula is highly sensitive to compact UV emission but mostly insensitive to hard X-rays. Our attempts to quantify the beaming of the soft and hard X-rays therefore strongly depends on the UV luminosity of the ULX in the centre of the nebula. We find that it is not possible to conclude a lack of geometrical beaming of hard X-rays from such sources via nebula feedback. [ABSTRACT FROM AUTHOR]

Published

2024

46. Pulse profile variability associated with the glitch of PSR J1048-5832.

Author

Liu, P, Yuan, J -P, Ge, M -Y, Ye, W -T, Zhou, S -Q, Dang, S -J, Zhou, Z -R, Gügercinoğlu, E, Wang, W -H, Wang, P, Li, A, Li, D, and Wang, N

Subjects

*FERMI Gamma-ray Space Telescope (Spacecraft), *NEUTRON stars, *RADIO telescopes, *EQUATIONS of state, *MOMENTS of inertia

Abstract

PSR J1048 |$-$| 5832 (B1046 |$-$| 58) is a Vela-like pulsar that has exhibited multiple glitch events. In this study, we analyse the timing data spanning nearly 16 yr, acquired from both the Fermi Gamma-ray Space Telescope and the Parkes 64 m radio telescope. As a result, a total of five glitches are detected within this data set. Among them, a previously unknown small glitch is newly found at MJD 56985(9) (November 24, 2014), making it the smallest glitch recorded from this source so far. The increments of the spin frequency and its first derivative are |$\Delta \nu \approx 2.2(3) \times 10^ {-8}$|  Hz, and |$\Delta \dot{\nu } \approx 3(2) \times 10^ {-15}$|  s |$^{-2}$|⁠ , respectively. Significant changes in the integrated normalized mean pulse profile are detected following three of the five glitch events, notably in the radio band. Although no evidence of a correlation is found between the spin-down rate and profile evolution, the jump phenomenon of |$W_{55}$| (pulse width at the 55% peak amplitude) after the glitch in the narrow mode suggests that the glitch may influence the profile change. We discuss the influence of glitches on the pulsar's emission properties in terms of platelet motion by a crustquake and also put constraints on the equation of state from the moment of inertia and response time-scales of involved superfluid layers inside the neutron star. [ABSTRACT FROM AUTHOR]

Published

2024

47. The TRAPUM Small Magellanic Cloud pulsar survey with MeerKAT – II. Nine new radio timing solutions and glitches from young pulsars.

Author

Carli, E, Antonopoulou, D, Burgay, M, Keith, M J, Levin, L, Liu, Y, Stappers, B W, Turner, J D, Barr, E D, Breton, R P, Buchner, S, Kramer, M, Padmanabh, P V, Possenti, A, Venkatraman Krishnan, V, Venter, C, Becker, W, Maitra, C, Haberl, F, and Thongmeearkom, T

Subjects

*SMALL magellanic cloud, *SUPERNOVA remnants, *NEUTRON stars, *MAGELLANIC clouds, PULSAR detection

Abstract

We report new radio timing solutions from a 3-yr observing campaign conducted with the MeerKAT and Murriyang telescopes for nine Small Magellanic Cloud pulsars, increasing the number of characterized rotation-powered extragalactic pulsars by 40 per cent. We can infer from our determined parameters that the pulsars are seemingly all isolated, that six are ordinary pulsars, and that three of the recent MeerKAT discoveries have a young characteristic age of under 100 kyr and have undergone a spin-up glitch. Two of the sources, PSRs J0040 |$-$| 7337 and J0048 |$-$| 7317, are energetic young pulsars with spin-down luminosities of the order of 10 |$^{36}$|  erg s |$^{-1}$|⁠. They both experienced a large glitch, with a change in frequency of about 30  |$\mu$| Hz, and a frequency derivative change of order |$-10^{-14}$|  Hz s |$^{-1}$|⁠. These glitches, the inferred glitch rate, and the properties of these pulsars (including potentially high inter-glitch braking indices) suggest these neutron stars might be Vela-like repeating glitchers and should be closely monitored in the future. The position and energetics of PSR J0048 |$-$| 7317 confirm it is powering a new pulsar wind nebula (PWN) detected as a radio continuum source; and similarly the association of PSR J0040 |$-$| 7337 with the PWN of supernova remnant (SNR) DEM S5 (for which we present a new Chandra image) is strengthened. Finally, PSR J0040 |$-$| 7335 is also contained within the same SNR but is a chance superposition. It has also been seen to glitch with a change of frequency of |$10^{-2}$|   |$\mu$| Hz. This work more than doubles the characterized population of SMC radio pulsars. [ABSTRACT FROM AUTHOR]

Published

2024

48. Searching for pulsars, magnetars, and fast radio bursts in the sculptor galaxy using MeerKAT.

Author

Hurter, H, Venter, C, Levin, L, Stappers, B W, Barr, E D, Breton, R P, Buchner, S, Carli, E, Kramer, M, Padmanabh, P V, Possenti, A, Prayag, V, and Turner, J D

Subjects

*MILKY Way, *STAR clusters, *STELLAR populations, *SUPERNOVA remnants, *NEUTRON stars, *MAGNETARS

Abstract

The Sculptor Galaxy (NGC 253), located in the Southern Hemisphere, far off the Galactic Plane, has a relatively high star-formation rate of about 7 M |$_{\odot }$|  yr−1 and hosts a young and bright stellar population, including several super star clusters and supernova remnants. It is also the first galaxy, apart from the Milky Way Galaxy to be associated with two giant magnetar flares. As such, it is a potential host of pulsars and/or fast radio bursts in the nearby Universe. The instantaneous sensitivity and multibeam sky coverage offered by MeerKAT therefore make it a favourable target. We searched for pulsars, radio-emitting magnetars, and fast radio bursts in NGC 253 as part of the TRAPUM large survey project with MeerKAT. We did not find any pulsars during a 4 h observation, and derive a flux density limit of 4.4 µJy at 1400 MHz, limiting the pseudo-luminosity of the brightest putative pulsar in this galaxy to 54 Jy kpc2. Assuming universality of pulsar populations between galaxies, we estimate that detecting a pulsar as bright as this limit requires NGC 253 to contain a pulsar population of ⪞20 000. We also did not detect any single pulses, and our single pulse search flux density limit is 62 mJy at 1284 MHz. Our search is sensitive enough to have detected any fast radio bursts and radio emission similar to the brighter pulses seen from the magnetar SGR J1935+2154 if they had occurred during our observation. [ABSTRACT FROM AUTHOR]

Published

2024

49. 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

50. Prospects for neutron star parameter estimation using gravitational waves from f modes associated with magnetar flares.

Author

Ball, Matthew, Frey, Raymond, and Merfeld, Kara

Subjects

*STELLAR oscillations, *GRAVITATIONAL waves, *NEUTRON stars, *LASER interferometers, *PARAMETER estimation

Abstract

Magnetar vibrational modes are theorized to be associated with energetic X-ray flares. Regular searches for gravitational waves from these modes have been performed by Advanced LIGO (Laser Interferometer Gravitational-wave Observatory) and Advanced Virgo, with no detections so far. Presently, search results are given in upper limits on the root sum square of the integrated gravitational-wave strain. However, the increased sensitivity of current detectors and the promise of future detectors invite the consideration of more astrophysically motivated methods. We present a framework for augmenting gravitational-wave searches to measure or place direct limits on magnetar astrophysical properties in various search scenarios using a set of phenomenological and analytical models. [ABSTRACT FROM AUTHOR]

Published

2024