Granular-aluminum superconducting detector for 6 keV X-rays and 2.2 MeV beta sources

Gabutti, A.; Gray, K. E.; Wagner, R. G.; Ono, Ronald H.

doi:10.1016/0168-9002(90)90270-g

Cited by 20 publications

(7 citation statements)

References 14 publications

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“…During the past three decades, a range of different materials were implemented. Among them are granular Al [14] and W [15], crystalline NbVN [16], NbN [17], Nb [18], TaN [19], and amorphous WSi [4]. Over the years material and fabrication quality have improved, leading to better and saturated X-ray SNSPDs (X-SNSPD) [19].…”

Section: Introductionmentioning

confidence: 99%

X-Ray Induced Secondary Particle Counting With Thin NbTiN Nanowire Superconducting Detector

Branny

Didier

Zichi

et al. 2021

IEEE Trans. Appl. Supercond.

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We characterized the performance of a biased superconducting nanowire to detect X-ray photons. The device, made of a 10 nm thin NbTiN film and fabricated on a dielectric substrate (SiO2, Nb3O5) detected 1000 times larger signal than anticipated from direct X-ray absorption. We attributed this effect to X-ray induced generation of secondary particles in the substrate. The enhancement corresponds to an increase in the flux by the factor of 3.6, relative to a state-of-the-art commercial Xray silicon drift detector. The detector exhibited 8.25 ns temporal recovery time and 82 ps timing resolution, measured using optical photons. Our results emphasise the importance of the substrate in superconducting X-ray single photon detectors.

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Section: Introductionmentioning

confidence: 99%

X-Ray Induced Secondary Particle Counting With Thin NbTiN Nanowire Superconducting Detector

Branny

Didier

Zichi

et al. 2021

IEEE Trans. Appl. Supercond.

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“…Strikingly, the signal amplitude distribution depends significantly on the photon energy spectrum.Already more than a decade before the development of superconducting nanowire single-photon detectors (SNSPD) for the optical and near-infrared wavelength range, serious efforts had been undertaken to adapt this detection principle for X-ray photons with keVenergies. 1,2,3,4 However, these preliminary X-ray detectors struggled with latching, making it difficult to operate them as self-recovering detectors in which superconductivity recovers after photon detection events (called continuous operation mode in this letter). The need to externally reduce the bias current to a value low enough for superconductivity to recover after a detection event results in long dead times and limits the count rates.Very fast and sensitive X-ray single-photon detectors from superconducting nanowires would be very interesting for applications where very high count rates, precise timing, a good signal-to-noise ratio and response in a wide spectral range for photon counting are required.Potential applications comprise experiments with synchrotron X-ray sources, free-electron lasers and hot plasmas (as in nuclear fusion experiments), all emitting bright and pulsed X-ray radiation.…”

mentioning

confidence: 99%

“…Already more than a decade before the development of superconducting nanowire single-photon detectors (SNSPD) for the optical and near-infrared wavelength range, serious efforts had been undertaken to adapt this detection principle for X-ray photons with keVenergies. 1,2,3,4 However, these preliminary X-ray detectors struggled with latching, making it difficult to operate them as self-recovering detectors in which superconductivity recovers after photon detection events (called continuous operation mode in this letter). The need to externally reduce the bias current to a value low enough for superconductivity to recover after a detection event results in long dead times and limits the count rates.…”

mentioning

confidence: 99%

An ultra-fast superconducting Nb nanowire single-photon detector for soft x-rays

Inderbitzin

Engel

Schilling

et al. 2012

Applied Physics Letters

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Although superconducting nanowire single-photon detectors (SNSPDs) are well studied regarding the detection of infrared/optical photons and keV-molecules, no studies on continuous X-ray photon counting by thick-film detectors have been reported so far. We fabricated a 100 nm thick niobium X-ray SNSPD (an X-SNSPD), and studied its detection capability of photons with keV-energies in continuous mode.The detector is capable to detect photons even at reduced bias currents of 0.4%, which is in sharp contrast to optical thin-film SNSPDs. No dark counts were recorded in extended measurement periods. Strikingly, the signal amplitude distribution depends significantly on the photon energy spectrum.Already more than a decade before the development of superconducting nanowire single-photon detectors (SNSPD) for the optical and near-infrared wavelength range, serious efforts had been undertaken to adapt this detection principle for X-ray photons with keVenergies. 1,2,3,4 However, these preliminary X-ray detectors struggled with latching, making it difficult to operate them as self-recovering detectors in which superconductivity recovers after photon detection events (called continuous operation mode in this letter). The need to externally reduce the bias current to a value low enough for superconductivity to recover after a detection event results in long dead times and limits the count rates.Very fast and sensitive X-ray single-photon detectors from superconducting nanowires would be very interesting for applications where very high count rates, precise timing, a good signal-to-noise ratio and response in a wide spectral range for photon counting are required.Potential applications comprise experiments with synchrotron X-ray sources, free-electron lasers and hot plasmas (as in nuclear fusion experiments), all emitting bright and pulsed X-ray radiation. In many medical imaging systems ultrafast X-ray single-photon detectors with energy resolution are desirable in order to reduce patient radiation dose. In the recently developing photon-counting X-ray computer tomography for example, long detection pulse durations can compromise the image quality by a possible overlap of succeeding photon pulses, as high photon fluxes have to be used in order to prevent motion blur. 5Recently, SNSPDs 6 and superconducting stripline detectors (SSLDs) 7,8,9,10 with superconducting film thicknesses of up to 50 nm were reported to be used in continuous mode for time-of-flight mass spectrometry (TOF-MS) of molecules with keV-energies, and ultrafast pulse recovery times and pulse rise times down to 380 ps ± 50 ps were reported. 11There is only one report on continuous X-ray photon counting with SNSPDs: Perez de Lara et al. 12 reported on the detection of 6 keV photons by a SNSPD from 5 nm thin NbN.However, there are no published studies on continuous X-ray photon detection in thick-film SNSPDs (called X-SNSPDs in this work), although they are promising candidates for ultrafast detectors in continuous mode.The absorptance of X-ray photons in thin-...

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“…This is in agreement with the expectations from the hot-spot model: as the hot-spot diameter is smaller than the conduction path width even for 50 keV photons, a bias current above a non-zero threshold [14] must be applied in order to detect photons efficiently. It has been demonstrated that this bias threshold can depend on the energy of detected β-particles [16] and keV ions [15] and also on the operation temperature [16]. At , however, we expect that the energy-dependent bias thresholds are larger than 460 µA (assuming a cylindrical hot-spot [14]), which is already in the latching regime.…”

Section: E Bias-current Dependencementioning

confidence: 92%

Soft X-Ray Single-Photon Detection With Superconducting Tantalum Nitride and Niobium Nanowires

Inderbitzin

Engel

Schilling

2013

IEEE Trans. Appl. Supercond.

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We have fabricated ultrafast dark count-free soft X-ray singlephoton detectors (X-SNSPDs) from TaN with various conduction path widths, and we compare their properties with corresponding data from a Nb X-SNSPD. The TaN X-SNSPDs offer an improved detector performance regarding device detection efficiency, latching and pulse amplitudes. Wide conduction paths allow for a certain energy-resolving capability in contrast to narrow TaN conduction paths. However, wide paths also limit the detection efficiency at low temperatures, which can be explained within a hot-spot model.

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Granular-aluminum superconducting detector for 6 keV X-rays and 2.2 MeV beta sources

Cited by 20 publications

References 14 publications

X-Ray Induced Secondary Particle Counting With Thin NbTiN Nanowire Superconducting Detector

X-Ray Induced Secondary Particle Counting With Thin NbTiN Nanowire Superconducting Detector

An ultra-fast superconducting Nb nanowire single-photon detector for soft x-rays

Soft X-Ray Single-Photon Detection With Superconducting Tantalum Nitride and Niobium Nanowires

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