High-resolution superconducting X-ray spectrometers with an active area of 282 μm×282 μm

Mears, C. A.; Labov, S. E.; Frank, Matthias; Netel, H.; Hiller, L. J.; Lindeman, M. A.; Chow, D.; Barfknecht, A.T.

doi:10.1109/77.622114

Cited by 14 publications

(8 citation statements)

References 17 publications

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“…The resistance Rb is used for biasing to the STJ and R, is used as a shunt for RF filtering [3]- [5]. The STJ has a dynamic resistance Rd of 100 kS1 and a capacitance C of 400 pF.…”

Section: B Performance Of the Squid Amplifier Using Simulated Signalsmentioning

confidence: 99%

Development of a compact system for high-resolution X-ray detection using a SQUID amplifier

Ikeda

Katô

Kawai

et al. 1999

IEEE Trans. Appl. Supercond.

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A compact system for an STJ-based high resolution X-ray detection system using a SQUID amplifier has been developed. A noise level of less than 4.8 m V at the SQUID output pulse height of 1.2 V for Nb-based S T J signals was achieved in the temperature range of 1.7-4.2K with good reproducibility under a n external magnetic field of about 0.01 Tesla, which was applied to suppress the Josephson current of the STJ. The results show the possibility of constructing a compact STJ-based X-ray detection system with an 'on-site' low noise SQUID preamplifier.

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“…The resistance Rb is used for biasing to the STJ and R, is used as a shunt for RF filtering [3]- [5]. The STJ has a dynamic resistance Rd of 100 kS1 and a capacitance C of 400 pF.…”

Section: B Performance Of the Squid Amplifier Using Simulated Signalsmentioning

confidence: 99%

Development of a compact system for high-resolution X-ray detection using a SQUID amplifier

Ikeda

Katô

Kawai

et al. 1999

IEEE Trans. Appl. Supercond.

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“…B is the angular frequency bandwidth, which is required for a measurement system (2%f B ) to measure signals. Equation (2) shows that I in ðmaxÞ decreases with increasing M in . The maximum feedback flux of the FLL circuit È f ðmaxÞ is…”

Section: Estimation Of Dynamic Range Drmentioning

confidence: 99%

“…1) Recently, an X-ray spectroscopy system that uses superconducting technologies has attracted much interests. 2,3) Cryogenic detectors are based on superconducting tunnel junctions (STJs) and superconducting transition edge sensors (TESs). They have been developed for next-generation X-ray microanalysis in the semiconductor industry and material science, 4) and for X-ray astronomy.…”

Section: Introductionmentioning

confidence: 99%

Array of Superconducting Quantum Interference Devices with Multiturn Input Coil

Morooka

Myoren

Takada

et al. 2004

Jpn. J. Appl. Phys.

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Arrays of dc-superconducting quantum interference devices (dc-SQUIDs) were investigated, in which each dc-SQUID element has a multiturn input coil. The dependence of flux noise on the number of turns of the input coil was studied for current amplifiers. SQUID arrays were fabricated by a Nb/AlO x /Nb Josephson tunnel junction fabrication process. Results show that the flux noise of the SQUID array amplifier does not depend on the turn number of the input coil. A SQUID array amplifier consisting of 128 dc-SQUID elements was fabricated, in which each element had a 7-turn input coil and a mutual inductance between the input coil and the SQUID loop of 460 pH. This amplifier showed an ultrahigh current resolution of 1 pA/Hz 0:5 and a maximum input current of 11 mA for signals of 50 kHz, which is sufficient bandwidth for X-ray detection applications. These values correspond to a large dynamic range of 87 dB. The flux-voltage characteristics of this SQUID array, however, showed asymmetric behavior, which originated from electronic resonance in stray capacitance and the mutual inductance between the SQUID loop and the multiturn input coil.

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“…1,2 Recently, superconducting tunnel junctions ͑STJ's͒ have attracted strong attention because of their application potential as particle and radiation detectors with high energy resolution. [3][4][5][6][7] Here the quasiparticles generated in the electrodes of the junction are detected by means of the tunneling conductivity. Simulating the irradiation event by electron beam scanning has provided useful information on the quasiparticle dynamics and for optimizing the performance of superconducting tunnel junction detectors, 8 because of the high spatial and temporal resolution achieved by this method.…”

Section: Imaging Of Vortices In Superconductors By Electron Beam Scanmentioning

confidence: 99%

Imaging of vortices in superconductors by electron beam scanning

Martin

Huebener

Grand

et al. 1998

Applied Physics Letters

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Abrikosov vortices trapped in a superconducting tunnel junction and oriented perpendicular to the barrier plane were imaged by electron beam scanning at 1.6 K. We have used NbAlOxNb junctions. As an important feature, the top Nb electrode was covered with a SiO2 film of 300 nm thickness, absorbing most of the 5 keV beam energy. The signal generating the image is explained by a model, assuming that the beam-induced electronic excitations in the SiO2 overlay film are trapped in the local magnetic field protruding from a vortex, resulting in an increased recombination rate. In addition to providing a novel approach to the imaging of the vortices in superconductors, our results are important for understanding quasiparticle losses in tunnel junction detectors.

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High-resolution superconducting X-ray spectrometers with an active area of 282 μm×282 μm

Cited by 14 publications

References 17 publications

Development of a compact system for high-resolution X-ray detection using a SQUID amplifier

Development of a compact system for high-resolution X-ray detection using a SQUID amplifier

Array of Superconducting Quantum Interference Devices with Multiturn Input Coil

Imaging of vortices in superconductors by electron beam scanning

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