Overview of the high-definition x-ray imager instrument on the Lynx x-ray surveyor

Falcone, A.; Kraft, Ralph; Bautz, Marshall W.; Gaskin, Jessica A.; Mulqueen, John A.; Swartz, Doug

doi:10.1117/1.jatis.5.2.021019

Cited by 20 publications

(16 citation statements)

References 15 publications

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“…The combination of the large collecting area of Lynx with a high spatial resolution (< 0.5 ) will allow us to map the fainter individual X-ray photons in greater detail. Although the spatial resolution of Athena (∼ 5 ) is insufficient to allow detailed mapping of the X-ray emissions, the spectral resolution of Athena's X-ray Integral Field Unit (X-IFU) is ∼ 2.5 eV up to energies of 7 keV (Barret et al 2016), surpassing both the High Definition X-ray Imager on board Lynx (∼ 70 eV -150 eV at energies 0.3 -5.9 keV) and ACIS (∼ 130 eV -280 eV at energies 1.49 -5.9 keV) (Falcone et al 2019). The high energy resolution of Athena will allow us to find more detailed spectra of the X-ray emissions at Saturn as well as that of the other planets.…”

Section: Discussionmentioning

confidence: 99%

Searching for Saturn’s X-rays during a rare Jupiter Magnetotail crossing using Chandra

Weigt

Dunn

Jackman

et al. 2021

Monthly Notices of the Royal Astronomical Society

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Every 19 years, Saturn passes through Jupiter’s ‘flapping’ magnetotail. Here, we report Chandra X-ray observations of Saturn planned to coincide with this rare planetary alignment and to analyse Saturn’s magnetospheric response when transitioning to this unique parameter space. We analyse three Director’s Discretionary Time (DDT) observations from the High Resolution Camera (HRC-I) on-board Chandra, taken on November 19, 21 and 23 2020 with the aim to find auroral and/or disk emissions. We infer the conditions in the kronian system by looking at coincident soft X-ray solar flux data from the Geostationary Operational Environmental Satellite (GOES) and Hubble Space Telescope (HST) observations of Saturn’s ultraviolet (UV) auroral emissions. The large Saturn-Sun-Earth angle during this time would mean that most flares from the Earth-facing side of the Sun would not have impacted Saturn. We find no significant detection of Saturn’s disk or auroral emissions in any of our observations. We calculate the 3σ upper band energy flux of Saturn during this time to be 0.9 - 3.04 × 10−14 erg cm−2 s−1 which agrees with fluxes found from previous modelled spectra of the disk emissions. We conclude by discussing the implications of this non-detection and how it is imperative that the next fleet of X-ray telescope (such as Athena and the Lynx mission concept) continue to observe Saturn with their improved spatial and spectral resolution and very enhanced sensitivity to help us finally solve the mysteries behind Saturn’s apparently elusive X-ray aurora.

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Section: Discussionmentioning

confidence: 99%

Searching for Saturn’s X-rays during a rare Jupiter Magnetotail crossing using Chandra

Weigt

Dunn

Jackman

et al. 2021

Monthly Notices of the Royal Astronomical Society

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“…Oct-Dec 2019 • Vol. 5 (4) payloads from aquatic environments and the opening of new launch sites for science programs. Although a combination of low source flux and possible condensation on the detector during flight prevented the WRXR spectrometer from obtaining observational constraints on the Vela SNR, instrument performance was a significant development step in technology maturation and as a pathfinder for upcoming suborbital payloads.…”

Section: Discussionmentioning

confidence: 99%

“…The WRXR was a technology-driven astrophysics payload that sought to demonstrate the performance of two technologies assigned the highest priority to NASA Astrophysics technology development in the 2019 Astrophysics Biennial Technology Report: 1 x-ray reflection gratings and an x-ray hybrid CMOS detector (HCD). Both technologies were studied or are actively under development for the Lynx flagship mission concept, [2][3][4] explorer and probe mission concepts, [5][6][7][8] and smaller missions, such as suborbital rocket payloads 9,10 and cubesats. 11 The WRXR, along with the Colorado Highresolution Echelle Stellar Spectrograph, 12 also enabled the first successful demonstrations of NASA water recovery technology for astrophysics suborbital rocket payloads.…”

Section: Introductionmentioning

confidence: 99%

Water Recovery X-Ray Rocket grating spectrometer

Miles

Hull

Schultz

et al. 2019

J. Astron. Telesc. Instrum. Syst.

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The Water Recovery X-Ray Rocket (WRXR) was a suborbital rocket payload that was launched and recovered in April 2018. The WRXR flew two technologies being developed for future large x-ray missions: x-ray reflection gratings and a hybrid CMOS detector (HCD). The large-format replicated gratings on the WRXR were measured in ground calibrations to have absolute single-order diffraction efficiency of ∼60%, ∼50%, and ∼35% at CVI, OVII, and OVIII emission energies, respectively. The HCD was operated with ∼6 e − read noise and ∼88 eV energy resolution at 0.5 keV. The WRXR was also part of a two-payload campaign that successfully demonstrated NASA sounding rocket water recovery technology for science payloads. The primary instrument, a soft x-ray grating spectrometer, targeted diffuse emission from the Vela supernova remnant over a field-of-view >10 deg 2 . The flight data show that the detector was operational during flight and detected x-ray events from an on-board calibration source, but there was no definitive detection of x-ray events from Vela. Flight results are presented along with a discussion of factors that could have contributed to the null detection.

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“…X-ray mirror technologies that were studied in detail by the Lynx team included silicon meta-shell optics developed by GSFC, 4 fullshell optics developed by Brera (INAF/Brera) and Marshall Spaceflight Center (MSFC), 5,6 and adjustable segmented optics developed by the SAO. 7,8 Similarly, multiple technologies were studied for the large-scale active sensor pixel array, dubbed the high-definition x-ray imager (HDXI) [9][10][11][12] and for the XGS. 13,14 The Lynx x-ray microcalorimeter (LXM) [15][16][17][18][19][20][21] is singular but has elements that have multiple candidate technologies.…”

Section: Designing An Observatorymentioning

confidence: 99%

“…HDXI detector candidate technologies are described in detail in this paper and elsewhere in the literature. [9][10][11][12] These detectors will be able to provide a low-noise, wide FOV, high-count rate capability (8000 ct s −1 ) option and will be able to support the high-angular resolution required by Lynx with ∼0.3 arc sec pixels. Key requirements for Lynx and ATHENA APS arrays compared to Chandra's ACIS-I array are summarized in Table 2.…”

Section: High-definition X-ray Imagermentioning

confidence: 99%

Lynx X-Ray Observatory: an overview

Gaskin

Swartz

Vikhlinin

et al. 2019

J. Astron. Telesc. Instrum. Syst.

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124

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Lynx, one of the four strategic mission concepts under study for the 2020 Astrophysics Decadal Survey, provides leaps in capability over previous and planned x-ray missions and provides synergistic observations in the 2030s to a multitude of space-and ground-based observatories across all wavelengths. Lynx provides orders of magnitude improvement in sensitivity, on-axis subarcsecond imaging with arcsecond angular resolution over a large field of view, and high-resolution spectroscopy for point-like and extended sources in the 0.2-to 10-keV range. The Lynx architecture enables a broad range of unique and compelling science to be carried out mainly through a General Observer Program. This program is envisioned to include detecting the very first seed black holes, revealing the high-energy drivers of galaxy formation and evolution, and characterizing the mechanisms that govern stellar evolution and stellar ecosystems. The Lynx optics and science instruments are carefully designed to optimize the science capability and, when combined, form an exciting architecture that utilizes relatively mature technologies for a cost that is compatible with the projected NASA Astrophysics budget. © The Authors. Published by SPIE under a Creative Commons Attribution 4.0 Unported License. Distribution or reproduction of this work in whole or in part requires full attribution of the original publication, including its DOI.

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Overview of the high-definition x-ray imager instrument on the Lynx x-ray surveyor

Cited by 20 publications

References 15 publications

Searching for Saturn’s X-rays during a rare Jupiter Magnetotail crossing using Chandra

Searching for Saturn’s X-rays during a rare Jupiter Magnetotail crossing using Chandra

Water Recovery X-Ray Rocket grating spectrometer

Lynx X-Ray Observatory: an overview

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