197 research outputs found
Measuring Neutron Star Radii via Pulse Profile Modeling with NICER
The Neutron-star Interior Composition Explorer (NICER) is an X-ray
astrophysics payload that will be placed on the International Space Station.
Its primary science goal is to measure with high accuracy the pulse profiles
that arise from the non-uniform thermal surface emission of rotation-powered
pulsars. Modeling general relativistic effects on the profiles will lead to
measuring the radii of these neutron stars and to constraining their equation
of state. Achieving this goal will depend, among other things, on accurate
knowledge of the source, sky, and instrument backgrounds. We use here simple
analytic estimates to quantify the level at which these backgrounds need to be
known in order for the upcoming measurements to provide significant constraints
on the properties of neutron stars. We show that, even in the
minimal-information scenario, knowledge of the background at a few percent
level for a background-to-source countrate ratio of 0.2 allows for a
measurement of the neutron star compactness to better than 10% uncertainty for
most of the parameter space. These constraints improve further when more
realistic assumptions are made about the neutron star emission and spin, and
when additional information about the source itself, such as its mass or
distance, are incorporated.Comment: Submitted to Ap
Instrument and method for X-ray diffraction, fluorescence, and crystal texture analysis without sample preparation
An X-ray diffraction and X-ray fluorescence instrument for analyzing samples having no sample preparation includes a X-ray source configured to output a collimated X-ray beam comprising a continuum spectrum of X-rays to a predetermined coordinate and a photon-counting X-ray imaging spectrometer disposed to receive X-rays output from an unprepared sample disposed at the predetermined coordinate upon exposure of the unprepared sample to the collimated X-ray beam. The X-ray source and the photon-counting X-ray imaging spectrometer are arranged in a reflection geometry relative to the predetermined coordinate
Method and System for Gamma-Ray Localization Induced Spacecraft Navigation Using Celestial Gamma-Ray Sources
A method and system for spacecraft navigation using distant celestial gamma-ray bursts which offer detectable, bright, high-energy events that provide well-defined characteristics conducive to accurate time-alignment among spatially separated spacecraft. Utilizing assemblages of photons from distant gamma-ray bursts, relative range between two spacecraft can be accurately computed along the direction to each burst's source based upon the difference in arrival time of the burst emission at each spacecraft's location. Correlation methods used to time-align the high-energy burst profiles are provided. The spacecraft navigation may be carried out autonomously or in a central control mode of operation
Miniaturized High-Speed Modulated X-Ray Source
A miniaturized high-speed modulated X-ray source (MXS) device and a method for rapidly and arbitrarily varying with time the output X-ray photon intensities and energies. The MXS device includes an ultraviolet emitter that emits ultraviolet light, a photocathode operably coupled to the ultraviolet light-emitting diode that emits electrons, an electron multiplier operably coupled to the photocathode that multiplies incident electrons, and an anode operably coupled to the electron multiplier that is configured to produce X-rays. The method for modulating MXS includes modulating an intensity of an ultraviolet emitter to emit ultraviolet light, generating electrons in response to the ultraviolet light, multiplying the electrons to become more electrons, and producing X-rays by an anode that includes a target material configured to produce X-rays in response to impact of the more electrons
Probing the Masses of the PSR J0621+1002 Binary System Through Relativistic Apsidal Motion
Orbital, spin and astrometric parameters of the millisecond pulsar PSR
J0621+1002 have been determined through six years of timing observations at
three radio telescopes. The chief result is a measurement of the rate of
periastron advance, omega_dot = 0.0116 +/- 0.0008 deg/yr. Interpreted as a
general relativistic effect, this implies the sum of the pulsar mass, m_1, and
the companion mass, m_2, to be M = m_1 + m_2 = 2.81 +/- 0.30 msun. The
Keplerian parameters rule out certain combinations of m_1 and m_2, as does the
non-detection of Shapiro delay in the pulse arrival times. These constraints,
together with the assumption that the companion is a white dwarf, lead to the
68% confidence maximum likelihood values of m_1 = 1.70(+0.32 -0.29) msun and
m_2 =0.97(+0.27 - 0.15) msun and to the 95% confidence maximum likelihood
values of m_1 = 1.70(+0.59 -0.63) msun and m_2 = 0.97(+0.43 -0.24) msun. The
other major finding is that the pulsar experiences dramatic variability in its
dispersion measure (DM), with gradients as steep as 0.013 pc cm^{-3} / yr. A
structure function analysis of the DM variations uncovers spatial fluctuations
in the interstellar electron density that cannot be fit to a single power law,
unlike the Kolmogorov turbulent spectrum that has been seen in the direction of
other pulsars. Other results from the timing analysis include the first
measurements of the pulsar's proper motion, mu = 3.5 +/- 0.3 mas / yr, and of
its spin-down rate, dP/dt = 4.7 x 10^{-20}, which, when corrected for kinematic
biases and combined with the pulse period, P = 28.8 ms, gives a characteristic
age of 1.1 x 10^{10} yr and a surface magnetic field strength of 1.2 x 10^{9}
G.Comment: Accepted by ApJ, 10 pages, 5 figure
Deciphering the Nature of the Pulsar Wind Nebula CTB 87 with XMM-Newton
CTB 87 (G74.9+1.2) is an evolved supernova remnant (SNR) which hosts a
peculiar pulsar wind nebula (PWN). The X-ray peak is offset from that observed
in radio and lies towards the edge of the radio nebula. The putative pulsar,
CXOU~J201609.2+371110, was first resolved with \textit{Chandra} and is
surrounded by a compact and a more extended X-ray nebula. Here we use a deep
{\textit{XMM-Newton}} observation to examine the morphology and evolutionary
stage of the PWN and to search for thermal emission expected from a supernova
shell or reverse shock interaction with supernova ejecta. We do not find
evidence of thermal X-ray emission from the SNR and place an upper limit on the
electron density of 0.05~cm for a plasma temperature keV.
The morphology and spectral properties are consistent with a 20~kyr-old
relic PWN expanding into a stellar wind-blown bubble. We also present the first
X-ray spectral index map from the PWN and show that we can reproduce its
morphology by means of 2D axisymmetric relativistic hydrodynamical simulations.Comment: 9 pages, 10 figures. Accepted for publication in MNRA
Development of Ground-testable Phase Fresnel Lenses in Silicon
Diffractive/refractive optics, such as Phase Fresnel Lenses (PFL's), offer
the potential to achieve excellent imaging performance in the x-ray and
gamma-ray photon regimes. In principle, the angular resolution obtained with
these devices can be diffraction limited. Furthermore, improvements in signal
sensitivity can be achieved as virtually the entire flux incident on a lens can
be concentrated onto a small detector area. In order to verify experimentally
the imaging performance, we have fabricated PFL's in silicon using gray-scale
lithography to produce the required Fresnel profile. These devices are to be
evaluated in the recently constructed 600-meter x-ray interferometry testbed at
NASA/GSFC. Profile measurements of the Fresnel structures in fabricated PFL's
have been performed and have been used to obtain initial characterization of
the expected PFL imaging efficiencies.Comment: Presented at GammaWave05: "Focusing Telescopes in Nuclear
Astrophysics", Bonifacio, Corsica, September 2005, to be published in
Experimental Astronomy, 8 pages, 3 figure
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