Modelling the resistive state in a transition edge sensor

Kozorezov, A. G.; Golubov, A. A.; Martin, D.; Korte, P. A. J. de; Lindeman, M. A.; Hijmering, R. A.; Kuur, J. van der; Hoevers, H.; Gottardi, L.; Kupriyanov, M. Yu.; Wigmore, J. K.

doi:10.1063/1.3621829

Cited by 44 publications

(38 citation statements)

References 13 publications

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“…Figure 4b presents the measured I C (T ) for a single 35 µm TES and a 140 µm TES. Assuming a Resistively Shunted Junction R(T , I ) model of a TES [20], we can derive a simple relation for α/β [16]:…”

Section: Resultsmentioning

confidence: 99%

Small Pitch Transition-Edge Sensors with Broadband High Spectral Resolution for Solar Physics

et al. 2012

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We are developing small pitch transition-edge sensor (TES) X-ray detectors optimized for solar astronomy. These devices are fabricated on thick Si substrates with embedded Cu heat-sink layer. We use 35 × 35 µm 2 Mo/Au TESs with 4.5 µm thick Au absorbers. We have tested devices with different geometric absorber stem contact areas with the TES and surrounding substrate area. This allows us to investigate the loss of athermal phonons to the substrate. Results show a correlation between the stem contact area and a broadening in the spectral line shape indicative of athermal phonon loss. When the contact area is minimized we have obtained exceptional broadband spectral resolution of 1.28 ± 0.03 eV at an energy of 1.5 keV, 1.58 ± 0.07 eV at 5.9 keV and 1.96 ± 0.08 eV at 8 keV. The linearity in the measured gain scale is understood in the context of the longitudinal proximity effect from the electrical bias leads resulting in transition characteristics that are strongly dependent upon TES size.

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Section: Resultsmentioning

confidence: 99%

Small Pitch Transition-Edge Sensors with Broadband High Spectral Resolution for Solar Physics

et al. 2012

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“…Using a proximity effect model of a TES we can calculate parameters that can be compared with experimental measurements, and the procedure for this is shown in Figure 1. Our model 20 is based on the numerical solution by iteration of the Usadel equations 21,22 in conjunction with the self-consistency equation, subject to appropriate boundary conditions. 23 The other inputs to the model are the sensor dimensions and the material parameters.…”

Section: Methodsmentioning

confidence: 99%

Proximity effect model for x-ray transition edge sensors

Harwin

Goldie

Withington

et al. 2018

High Energy, Optical, and Infrared Detectors for Astronomy VIII

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Transition Edge Sensors are ultra-sensitive superconducting detectors with applications in many areas of research, including astrophysics. The device consists of a superconducting thin film, often with additional normal metal features, held close to its transition temperature and connected to two superconducting leads of a higher transition temperature. There is currently no way to reliably assess the performance of a particular device geometry or material composition without making and testing the device. We have developed a proximity effect model based on the Usadel equations to predict the effects of device geometry and material composition on sensor performance. The model is successful in reproducing I − V curves for two devices currently under study. We use the model to suggest the optimal size and geometry for TESs, considering how small the devices can be made before their performance is compromised. In the future, device modelling prior to manufacture will reduce the need for time-consuming and expensive testing.

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“…It can be shown that in the range of frequencies where Z T ES (ω) significantly differs from Z 0 T ES (ω) frequency dependencies of £ 0 (ω) and τ eff (ω) can be neglected. As a result the expression (5) becomes [7] Figure 3(b) shows the calculated impedance at a constant TES current at different temperatures, illustrating the effect of the second higher frequency pole. The numbers are chosen for illustrative purposes only and the curves sequence does not reflect any experiment imposing specific constraints on TES temperature, current or bath temperature.…”

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confidence: 96%

“…In our recent work [7] we proposed to describe the resistive state of TES within the model of resistively shunted conductive junction (RSJ). TES is a special kind of weak superconducting link designed with Andreev mirrors at the lead/TES interfaces to prevent energy leak into leads.…”

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confidence: 99%

Modelling the Resistive State in a Transition Edge Sensor

Kozorezov

Golubov²,

Martin

2012

J Low Temp Phys

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We have developed a model for the resistive transition in a transition edge sensor (TES) based on the model of a resistively shunted junction, taking into account phase-slips of a superconducting system across the barriers of the tilted washing board potential. We obtained analytical expressions for the resistance of the TES, R(T , I ), and its partial logarithmic derivatives α I and β I as functions of temperature and current. We have shown that all the major parameters describing the resistive state of the TES are determined by the dependence on temperature of the Josephson critical current, rather than by intrinsic properties of the S-N transition. The complex impedance of a pristine TES exhibits two-pole behaviour due to its own intrinsic reactance.

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Modelling the resistive state in a transition edge sensor

Cited by 44 publications

References 13 publications

Small Pitch Transition-Edge Sensors with Broadband High Spectral Resolution for Solar Physics

Small Pitch Transition-Edge Sensors with Broadband High Spectral Resolution for Solar Physics

Proximity effect model for x-ray transition edge sensors

Modelling the Resistive State in a Transition Edge Sensor

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