Search results for "Anticoincidence"

showing 4 items of 4 documents

Development of a TES based Cryo-Anticoincidence for a large array of microcalorimeters

2009

The employment of large arrays of microcalorimeters in space missions (IXO, EDGE/XENIA)[1][2][3], requires the presence of an anticoincidence detector to remove the background due to the particles, with a rejection efficiency at least equal to Suzaku (98%) [1]. A new concept of anticoincidence is under development to match the very tight thermal requirements and to simplify the design of the electronic chain. The idea is to produce a Cryo-AntiCoincidence (Cryo-AC) based on a silicon absorber and read by a TES (Transition-Edge Sensor). This configuration would ensure very good performances in terms of efficiency, time response and signal to noise ratio. We present the results of estimations,…

Physicsbusiness.industryLarge arrayBolometerDetectorParticle detectorSpace explorationlaw.inventionPhysics and Astronomy (all)OpticsSignal-to-noise ratioMicrocalorimeterlawThermalDevelopment (differential geometry)Particle detectorX-ray detectors microcalorimeters backgroundAnticoincidencebusinessAnticoincidence; Microcalorimeter; Particle detector; TES; X ray detector; Physics and Astronomy (all)TESX ray detectorAIP Conference Proceedings
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The Cryogenic AntiCoincidence Detector Project for ATHENA+: An Overview Up to the Present Status

2014

ATHENA+ is a space mission proposal for the next ESA L2-L3 slot. One of the focal plane instruments is the X-ray integral field unit (X-IFU) working in the energy range 0.3–10 keV. It is a multi-array based on TES detectors aimed at characterizing faint or diffuse sources (e.g. WHIM or galaxy outskirt). The X-IFU will be able to achieve the required sensitivity if a low background is guaranteed. The studies performed by GEANT4 simulations depict a scenario where the use of an active anticoincidence (AC) is mandatory to reduce the background expected in L2 orbit down to the goal level of 0.005 cts cm $$^{-2}$$  s $$^{-1}$$  keV $$^{-1}$$ . This is possible using a cryogenic anticoincidence (…

PhysicsSiliconbusiness.industryAnticoincidence detectorDetectorOrder (ring theory)SpaceTES Silicon Iridium Anticoincidence detector SpaceIridiumCondensed Matter PhysicsAtomic and Molecular Physics and OpticsGalaxyOpticsCardinal pointAnticoincidence detector; Iridium; Silicon; Space; TES; Atomic and Molecular Physics and Optics; Materials Science (all); Condensed Matter PhysicsSettore FIS/05 - Astronomia E AstrofisicaAtomic and Molecular PhysicsOrbit (dynamics)General Materials ScienceSensitivity (control systems)Materials Science (all)and OpticsbusinessTESEnergy (signal processing)
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The Cryogenic AntiCoincidence detector for ATHENA: the progress towards the final pixel design

2014

“The Hot and Energetic Universe” is the scientific theme approved by the ESA SPC for a Large mission to be flown in the next ESA slot (2028th) timeframe. ATHENA is a space mission proposal tailored on this scientific theme. It will be the first X-ray mission able to perform the so-called “Integral field spectroscopy”, by coupling a high-resolution spectrometer, the X-ray Integral Field Unit (X-IFU), to a high performance optics so providing detailed images of its field of view (5’ in diameter) with an angular resolution of 5” and fine energy-spectra (2.5eV@E<7keV). The X-IFU is a kilo-pixel array based on TES (Transition Edge Sensor) microcalorimeters providing high resolution spectroscopy …

SimulationsSiliconWarm–hot intergalactic mediumField of viewOrbital mechanicsOpticsField spectroscopyGalactic astronomyX-raysElectronicAngular resolutionOptical and Magnetic MaterialsElectrical and Electronic EngineeringAnticoincidenceImage resolutionSpectroscopyPhysicsSpatial resolutionEquipment and servicesSpectrometerSpectrometersbusiness.industrySensorsApplied MathematicsDetectorComputer Science Applications1707 Computer Vision and Pattern RecognitionCondensed Matter PhysicsATHENAAnticoincidence; ATHENA; Cryogenic detectors; TES; Electronic Optical and Magnetic Materials; Condensed Matter Physics; Computer Science Applications1707 Computer Vision and Pattern Recognition; Applied Mathematics; Electrical and Electronic EngineeringCryogenic detectorsTransition edge sensorbusinessTES
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The cryogenic anticoincidence detector for ATHENA-XMS: preliminary results from the new prototype

2012

ATHENA has been the re-scoped IXO mission, and one of the foreseen focal plane instrument was the X-ray Microcalorimeter Spectrometer (XMS) working in the energy range 0.3-10 keV, which was a kilo-pixel array based on TES (Transition Edge Sensor) detectors. The need of an anticoincidence (AC) detector is legitimated by the results performed with GEANT4 simulations about the impact of the non x-ray background onto XMS at L2 orbit (REQ. < 0.02 cts/cm2/s/keV). Our consortium has both developed and tested several samples, with increasing area, in order to match the large area of the XMS (64 mm2). Here we show the preliminary results from the last prototype. The results achieved in this work off…

Anticoincidence detectorLow temperature DetectorAnticoincidence detectorsAstrophysicsOrbital mechanicslaw.inventionOpticslawElectronicOptical and Magnetic MaterialsElectrical and Electronic EngineeringAnticoincidence detectors; High Energy Astrophysics; Low temperature Detectors; TES; Electronic Optical and Magnetic Materials; Condensed Matter Physics; Computer Science Applications1707 Computer Vision and Pattern Recognition; Applied Mathematics; Electrical and Electronic EngineeringPhysicsLow temperature DetectorsSpectrometerbusiness.industryApplied MathematicsElectronic Optical and Magnetic MaterialBolometerDetectorComputer Science Applications1707 Computer Vision and Pattern RecognitionCondensed Matter PhysicsApplied MathematicCardinal pointMillimeterSatelliteTransition edge sensorHigh Energy AstrophysicbusinessTESHigh Energy AstrophysicsSPIE Proceedings
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