35 research outputs found
Evidence for a Binary Companion to the Central Compact Object 1E 1207.4-5209
Unique among neutron stars, 1E 1207.4-5209 is an X-ray pulsar with a spin
period of 424 ms that contains at least two strong absorption features in its
energy spectrum. This neutron star has been identified as a member of the
radio-quiet compact central objects in supernova remnants. It has been found
that 1E 1207.4-5209 is not spinning down monotonically suggesting that this
neutron star undergoes strong, frequent glitches, contains a fall-back disk, or
possess a binary companion. Here, we report on a sequence of seven XMM-Newton
observations of 1E 1207.4-5209 performed during a 40 day window in June/July
2005. Due to unanticipated variance in the phase measurements beyond the
statistical uncertainties, we could not identify a unique phase-coherent timing
solution. The three most probable timing solutions give frequency time
derivatives of +0.9, -2.6, and +1.6 X 10^(-12) Hz/s (listed in descending order
of significance). We conclude that the local frequency derivative during our
XMM-Newton observing campaign differs from the long-term spin-down rate by more
than an order of magnitude, effectively ruling out glitch models for 1E
1207.4-5209. If the long-term spin frequency variations are caused by timing
noise, the strength of the timing noise in 1E 1207.4-5209 is much stronger than
in other pulsars with similar period derivatives. Therefore, it is highly
unlikely that the spin variations are caused by the same physical process that
causes timing noise in other isolated pulsars. The most plausible scenario for
the observed spin irregularities is the presence of a binary companion to 1E
1207.4-5209. We identified a family of orbital solutions that are consistent
with our phase-connected timing solution, archival frequency measurements, and
constraints on the companions mass imposed by deep IR and optical observations.Comment: 8 pages, 4 figures. To be published in the proceedings of "Isolated
Neutron Stars: from the Interior to the Surface" (April 24-28, 2006) - eds.
D. Page, R. Turolla & S. Zan
Studying Millisecond Pulsars in X-rays
Millisecond pulsars represent an evolutionarily distinct group among rotation-powered pulsars. Outside the radio band, the soft X-ray range (--10 keV) is most suitable for studying radiative mechanisms operating in these fascinating objects. X-ray observations revealed diverse properties of emission from millisecond pulsars. For the most of them, the bulk of radiation is of a thermal origin, emitted from small spots (polar caps) on the neutron star surface heated by relativistic particles produced in pulsar acceleration zones. On the other hand, a few other very fast rotating pulsars exhibit almost pure nonthermal emission generated, most probably, in pulsar magnetospheres. There are also examples of nonthermal emission detected from X-ray nebulae powered by millisecond pulsars, as well as from pulsar winds shocked in binary systems with millisecond pulsars as companions. These and other most important results obtained from X-ray observations of millisecond pulsars are reviewed in this paper, as well as results from the search for millisecond pulsations in X-ray flux of the radio-quite neutron star RX J1856.5-3754
Importance of Compton scattering to radiation spectra of isolated neutron stars
Model atmospheres of isolated neutron stars with low magnetic field are
calculated with Compton scattering taking into account. Models with effective
temperatures 1, 3 and 5 MK, with two values of surface gravity log(g)g = 13.9
and 14.3), and different chemical compositions are calculated. Radiation
spectra computed with Compton scattering are softer than the computed with
Thomson scattering at high energies (E > 5 keV) for hot (T_eff > 1 MK)
atmospheres with hydrogen-helium composition. Compton scattering is more
significant to hydrogen models with low surface gravity. The emergent spectra
of the hottest (T_eff > 3 MK) model atmospheres can be described by diluted
blackbody spectra with hardness factors ~ 1.6 - 1.9. Compton scattering is less
important for models with solar abundance of heavy elements.Comment: Proceedings of the 363. WE-Heraeus Seminar on: Neutron Stars and
Pulsars (Posters and contributed talks) Physikzentrum Bad Honnef, Germany,
May.14-19, 2006, eds. W.Becker, H.H.Huang, MPE Report 291, pp.173-17
UV emission from young and middle-aged pulsars: Connecting X-rays with the optical
We present the UV spectroscopy and timing of three nearby pulsars (Vela,
B0656+14 and Geminga) recently observed with the Space Telescope Imaging
Spectrograph. We also review the optical and X-ray properties of these pulsars
and establish their connection with the UV properties. We show that the
multiwavelengths properties of neutron stars (NSs) vary significantly within
the sample of middle-aged pulsars. Even larger differences are found between
the thermal components of Ge-minga and B0656+14 as compared to those of
radio-quiet isolated NSs. These differences could be attributed to different
properties of the NS surface layers.Comment: To appear in Astrophysics and Space Science, Proceedings of "Isolated
Neutron Stars: from the Interior to the Surface", eds. D. Page, R. Turolla
and S. Zane; 10 pages, 4 figures, 3 table
The Puzzles of RX J1856.5-3754: Neutron Star or Quark Star?
We discuss recent Chandra and XMM-Newton observations of the bright isolated
neutron star RX J1856.5-3754 and suggest that the absence of any line features
is due to effects of a high magnetic field strength (~10^13 G). Using different
models for the temperature distribution across the neutron star surface
assuming blackbody emission to fit the optical and X-ray spectrum and we derive
a conservative lower limit of the "apparent" neutron star radius of 16.5 km x
(d/117 pc). This corresponds to the radius for the "true" (de-redshifted)
radius of 14 km for a 1.4 Msun neutron star, indicating a stiff equation of
state at high densities. A comparison of the result with mass-radius diagrams
shows that quark stars and neutron stars with quark matter cores can be ruled
out with high confidence.Comment: 6 page, 2 figures, "The Restless High-Energy Universe" Proceedings of
the symposium dedicated to six years of successful BeppoSAX operations
Amsterdam, May 5-8, 200
Guiding the Way to Gamma-Ray Sources: X-ray Studies of Supernova Remnants
Supernova remnants have long been suggested as a class of potential
counterparts to unidentified gamma-ray sources. The mechanisms by which such
gamma-rays can arise may include emission from a pulsar associated with a
remnant, or a variety of processes associated with energetic particles
accelerated by the SNR shock. Imaging and spectral observations in the X-ray
band can be used to identify properties of the remnants that lead to gamma-ray
emission, including the presence of pulsar-driven nebulae, nonthermal X-ray
emission from the SNR shells, and the interaction of SNRs with dense
surrounding material.Comment: 16 pages, 11 figures, To appear in the proceedings of the workshop:
"The Nature of the Unidentified Galactic Gamma-Ray Sources" held at INAOE,
Mexico, October 2000, (A.Carraminana, O. Reiner and D. Thompson, eds.
A multiwavelength study of the supernova remnant G296.8-0.3
We report XMM-Newton observations of the Galactic supernova remnant
G296.8-0.3, together with complementary radio and infrared data. The spatial
and spectral properties of the X-ray emission, detected towards G296.8-0.3, was
investigated in order to explore the possible evolutionary scenarios and the
physical connexion with its unusual morphology detected at radio frequencies.
G296.8-0.3 displays diffuse X-ray emission correlated with the peculiar radio
morphology detected in the interior of the remnant and with the shell-like
radio structure observed to the northwest side of the object. The X-ray
emission peaks in the soft/medium energy range (0.5-3.0 keV). The X-ray
spectral analysis confirms that the column density is high (NH \sim 0.64 x
10^{22} cm^{-2}) which supports a distant location (d>9 kpc) for the SNR. Its
X-ray spectrum can be well represented by a thermal (PSHOCK) model, with kT
\sim 0.86 keV, an ionization timescale of 6.1 x 10^{10} cm^{-3} s, and low
abundance (0.12 Z_sun). The 24 microns observations show shell-like emission
correlated with part of the northwest and southeast boundaries of the SNR. In
addition a point-like X-ray source is also detected close to the geometrical
center of the radio SNR. The object presents some characteristics of the
so-called compact central objects (CCO). Its X-ray spectrum is consistent with
those found at other CCOs and the value of NH is consistent with that of
G296.8-0.3, which suggests a physical connexion with the SNR.Comment: Accepted for publication in Astrophysics & Space Scienc
Studies of Neutron Stars at Optical/IR Wavelengths
In the last years, optical studies of Isolated Neutron Stars (INSs) have expanded from the more classical rotation-powered ones to other categories, like the Anomalous X-ray Pulsars (AXPs) and the Soft Gamma-ray Repeaters (SGRs), which make up the class of the magnetars, the radio-quiet INSs with X-ray thermal emission and, more recently, the enigmatic Compact Central Objects (CCOs) in supernova remnants. Apart from 10 rotation-powered pulsars, so far optical/IR counterparts have been found for 5 magnetars and for 4 INSs. In this work we present some of the latest observational results obtained from optical/IR observations of different types of INSs
Electron-positron Annihilation Lines and Decaying Sterile Neutrinos
If massive sterile neutrinos exist, their decays into photons and/or
electron-positron pairs may give rise to observable consequences. We consider
the possibility that MeV sterile neutrino decays lead to the diffuse positron
annihilation line in the Milky Way center, and we thus obtain bounds on the
sterile neutrino decay rate s from relevant
astrophysical/cosmological data. Also, we expect a soft gamma flux of ph cm s from the Milky Way
center which shows up as a small MeV bump in the background photon spectrum.
Furthermore, we estimate the flux of active neutrinos produced by sterile
neutrino decays to be cm s passing through the earth.Comment: Accepted for publication in Astrophysics & Space Scienc
Internal heating and thermal emission from old neutron stars: Constraints on dense-matter and gravitational physics
The equilibrium composition of neutron star matter is achieved through weak
interactions (direct and inverse beta decays), which proceed on relatively long
time scales. If the density of a matter element is perturbed, it will relax to
the new chemical equilibrium through non-equilibrium reactions, which produce
entropy that is partly released through neutrino emission, while a similar
fraction heats the matter and is eventually radiated as thermal photons. We
examined two possible mechanisms causing such density perturbations: 1) the
reduction in centrifugal force caused by spin-down (particularly in millisecond
pulsars), leading to "rotochemical heating", and 2) a hypothetical
time-variation of the gravitational constant, as predicted by some theories of
gravity and current cosmological models, leading to "gravitochemical heating".
If only slow weak interactions are allowed in the neutron star (modified Urca
reactions, with or without Cooper pairing), rotochemical heating can account
for the observed ultraviolet emission from the closest millisecond pulsar, PSR
J0437-4715, which also provides a constraint on |dG/dt| of the same order as
the best available in the literature.Comment: 6 pages, 7 figures. To appear in the proceedings of "Isolated Neutron
Stars: from the Interior to the Surface", a conference held in London in
April 2006 (special issue of Astrophysics and Space Science, edited by Dany
Page, Roberto Turolla, & Silvia Zane