161 research outputs found
Hard X-ray Quiescent Emission in Magnetars via Resonant Compton Upscattering
Non-thermal quiescent X-ray emission extending between 10 keV and around 150
keV has been seen in about 10 magnetars by RXTE, INTEGRAL, Suzaku, NuSTAR and
Fermi-GBM. For inner magnetospheric models of such hard X-ray signals, inverse
Compton scattering is anticipated to be the most efficient process for
generating the continuum radiation, because the scattering cross section is
resonant at the cyclotron frequency. We present hard X-ray upscattering spectra
for uncooled monoenergetic relativistic electrons injected in inner regions of
pulsar magnetospheres. These model spectra are integrated over bundles of
closed field lines and obtained for different observing perspectives. The
spectral turnover energies are critically dependent on the observer viewing
angles and electron Lorentz factor. We find that electrons with energies less
than around 15 MeV will emit most of their radiation below 250 keV, consistent
with the turnovers inferred in magnetar hard X-ray tails. Electrons of higher
energy still emit most of the radiation below around 1 MeV, except for
quasi-equatorial emission locales for select pulse phases. Our spectral
computations use a new state-of-the-art, spin-dependent formalism for the QED
Compton scattering cross section in strong magnetic fields.Comment: 5 pages, 2 figures, to appear in Proc. "Physics of Neutron Stars -
2017," Journal of Physics: Conference Series, eds. G. G. Pavlov, et al., held
in Saint Petersburg, Russia, 10-14 July, 201
Evidence for an abundant old population of Galactic ultra long period magnetars and implications for fast radio bursts
Two recent discoveries, namely PSR J0901-4046 and GLEAM-X J162759.5-523504.3
(hereafter GLEAM-X J1627), have corroborated an extant population of radio-loud
periodic sources with long periods (76 s and 1091 s respectively) whose
emission can hardly be explained by rotation losses. We argue that GLEAM-X
J1627 is a highly-magnetized object consistent with a magnetar (an ultra long
period magnetar - ULPM), and demonstrate it is unlikely to be either a
magnetically or a rotationally-powered white dwarf. By studying these sources
together with previously detected objects, we find there are at least a handful
of promising candidates for Galactic ULPMs. The detections of these objects
imply a substantial number, and for PSR
J0901--4046 like and GLEAM-X J1627 like objects, respectively, within our
Galaxy. These source densities, as well as cooling age limits from
non-detection of thermal X-rays, Galactic offsets, timing stability and dipole
spindown limits, all imply the ULPM candidates are substantially older than
confirmed Galactic magnetars and that their formation channel is a common one.
Their existence implies widespread survival of magnetar-like fields for several
Myr, distinct from the inferred behaviour in confirmed Galactic magnetars.
ULPMs may also constitute a second class of FRB progenitors which could
naturally exhibit very long periodic activity windows. Finally, we show that
existing radio campaigns are biased against detecting objects like these and
discuss strategies for future radio and X-ray surveys to identify more such
objects. We estimate that more such objects should be detected
with SKA-MID and DSA-2000.Comment: 22 pages, 10 figures. Published in MNRA
Radio pulsations from the -ray millisecond pulsar PSR J2039-5617
The predicted nature of the candidate redback pulsar 3FGL\,J2039.65618 was
recently confirmed by the discovery of -ray millisecond pulsations
(Clark et al. 2020, hereafter Paper\,I), which identify this -ray
source as \msp. We observed this object with the Parkes radio telescope in 2016
and 2019. We detect radio pulsations at 1.4\,GHz and 3.1\,GHz, at the 2.6ms
period discovered in -rays, and also at 0.7\,GHz in one 2015 archival
observation. In all bands, the radio pulse profile is characterised by a single
relatively broad peak which leads the main -ray peak. At 1.4\,GHz we
found clear evidence of eclipses of the radio signal for about half of the
orbit, a characteristic phenomenon in redback systems, which we associate with
the presence of intra-binary gas. From the dispersion measure of
\,pc\,cm we derive a pulsar distance of \,kpc
or \,kpc, depending on the assumed Galactic electron density model.
The modelling of the radio and -ray light curves leads to an
independent determination of the orbital inclination, and to a determination of
the pulsar mass, qualitatively consistent to the results in Paper\,I.Comment: 18 pages, accepted for publication on MNRA
Neutrinos, Cosmic Rays and the MeV Band
The possible association of the blazar TXS 0506+056 with a high-energy
neutrino detected by IceCube holds the tantalizing potential to answer three
astrophysical questions: 1. Where do high-energy neutrinos originate? 2. Where
are cosmic rays produced and accelerated? 3. What radiation mechanisms produce
the high-energy {\gamma}-rays in blazars? The MeV gamma-ray band holds the key
to these questions, because it is an excellent proxy for photo-hadronic
processes in blazar jets, which also produce neutrino counterparts. Variability
in MeV gamma-rays sheds light on the physical conditions and mechanisms that
take place in the particle acceleration sites in blazar jets. In addition,
hadronic blazar models also predict a high level of polarization fraction in
the MeV band, which can unambiguously distinguish the radiation mechanism.
Future MeV missions with a large field of view, high sensitivity, and
polarization capabilities will play a central role in multi-messenger
astronomy, since pointed, high-resolution telescopes will follow neutrino
alerts only when triggered by an all-sky instrument.Comment: White paper submitted to the Astro2020 Decadal Surve
Prospects for Pulsar Studies at MeV Energies
Enabled by the Fermi Large Area Telescope, we now know that pulsars fill the gamma-ray sky, and we are beginning to understand their emission mechanism and their distribution throughout the Galaxy. To address key questions calls for a sensitive, wide-field MeV telescope, which can detect the population of MeV-peaked pulsars hinted at by Fermi
The high energy X-ray probe (HEX-P): magnetars and other isolated neutron stars
© 2024 The Author(s). This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY), https://creativecommons.org/licenses/by/4.0/The hard X-ray emission from magnetars and other isolated neutron stars remains under-explored. An instrument with higher sensitivity to hard X-rays is critical to understanding the physics of neutron star magnetospheres and also the relationship between magnetars and Fast Radio Bursts (FRBs). High sensitivity to hard X-rays is required to determine the number of magnetars with hard X-ray tails, and to track transient non-thermal emission from these sources for years post-outburst. This sensitivity would also enable previously impossible studies of the faint non-thermal emission from middle-aged rotation-powered pulsars (RPPs), and detailed phase-resolved spectroscopic studies of younger, bright RPPs. The High Energy X-ray Probe (HEX-P) is a probe-class mission concept that will combine high spatial resolution X-ray imaging ( < 5 arcsec half-power diameter (HPD) at 0.2–25 keV) and broad spectral coverage (0.2–80 keV) with a sensitivity superior to current facilities (including XMM-Newton and NuSTAR). HEX-P has the required timing resolution to perform follow-up observations of sources identified by other facilities and positively identify candidate pulsating neutron stars. Here we discuss how HEX-P is ideally suited to address important questions about the physics of magnetars and other isolated neutron stars.Peer reviewe
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