173 research outputs found
NICER: Neutron Star Interior Composition ExploreR and SEXTANT
No abstract availabl
Pulsar Navigation and X-ray Communication Demonstrations with the NICER Payload on the ISS
No abstract availabl
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
X-ray CCDs for space applications : calibration, radiation hardness, and use for measuring the spectrum of the cosmic X-ray background
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Physics, 1995.Includes bibliographical references (200-202).by Keith Charles Gendreau.Ph.D
Formation Control for the MAXIM Mission
Over the next twenty years, a wave of change is occurring in the space-based scientific remote sensing community. While the fundamental limits in the spatial and angular resolution achievable in spacecraft have been reached, based on today s technology, an expansive new technology base has appeared over the past decade in the area of Distributed Space Systems (DSS). A key subset of the DSS technology area is that which covers precision formation flying of space vehicles. Through precision formation flying, the baselines, previously defined by the largest monolithic structure which could fit in the largest launch vehicle fairing, are now virtually unlimited. Several missions including the Micro-Arcsecond X-ray Imaging Mission (MAXIM), and the Stellar Imager will drive the formation flying challenges to achieve unprecedented baselines for high resolution, extended-scene, interferometry in the ultraviolet and X-ray regimes. This paper focuses on establishing the feasibility for the formation control of the MAXIM mission. MAXIM formation flying requirements are on the order of microns, while Stellar Imager mission requirements are on the order of nanometers. This paper specifically addresses: (1) high-level science requirements for these missions and how they evolve into engineering requirements; and (2) the development of linearized equations of relative motion for a formation operating in an n-body gravitational field. Linearized equations of motion provide the ground work for linear formation control designs
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
Long-term study of the first Galactic ultraluminous X-ray source Swift J0243.6+6124 using NICER
We present the results obtained from detailed X-ray timing and spectral
studies of X-ray pulsar Swift J0243.6+6124 during its giant and normal X-ray
outbursts between 2017 and 2023 observed by the Neutron star Interior
Composition Explorer (NICER). We focused on the timing analysis of the normal
outbursts. A distinct break is found in the power density spectra of the
source. The corresponding break frequency and slope of power-laws around the
break vary with luminosity, indicating the change in accretion dynamics with
mass accretion rate. Interestingly, we detected quasi-periodic oscillations
within a specific luminosity range, providing further insights into the
underlying physical processes. We also studied the neutron star spin period
evolution and a luminosity variation in pulse profile during the recent 2023
outburst. The spectral analysis was conducted comprehensively for the giant and
all other normal outbursts. We identified a double transition at luminosities
of 7.510 and 2.110 erg s in the
evolution of continuum parameters like photon index and cutoff energy with
luminosity. This indicates three distinct accretion modes experienced by the
source mainly during the giant X-ray outburst. A soft blackbody component with
a temperature of 0.08-0.7 keV is also detected in spectra. The observed
temperature undergoes a discontinuous transition when the pulsar evolves from a
sub- to super-Eddington state. Notably, in addition to an evolving 6-7 keV iron
line complex, a 1 keV emission line was observed during the super-Eddington
state of the source, implying the X-ray reflection from the accretion disc or
outflow material.Comment: This paper is accepted now in Astrophysical journa
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
Spectral and timing evolution of the black hole transient MAXI J1727-203 with NICER
MAXI J1727-203 is a new X-ray transient discovered on 5 June 2018. A hard-to-soft state transition at the beginning of the outburst led to the identification as a black hole candidate. MAXI J1727-203 was monitored with the Neutron Star Interior Composition Explorer (NICER) on an almost daily basis from the beginning of the outburst. We present a spectral and timing analysis of the full outburst of the source, which lasted approximately four months. A preliminary spectral analysis suggest that the accretion disk component can was detected throughout the entire outburst, with temperatures ranging from ~0.4 keV (in the soft state), down to ~0.2 keV near the end of the outburst when the source was in the hard state. The power spectrum in the hard state shows broadband noise up to 10 Hz, with no detection of any quasi-periodic oscillations. We argue that the system's characteristics are not consistent with those expected for a neutron star and that they are particularly reminiscent of the black hole X-ray binaries XTE J1118+480 and Cyg X-1
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