Thermal Conductance Engineering for High-Speed TES Microcalorimeters

Many current and future applications for superconducting transition-edge sensor (TES) microcalorimeters require significantly faster pulse response than is currently available. X-ray spectroscopy experiments at next-generation synchrotron light sources need to successfully capture very large fluxes of photons, while detectors at free-electron laser facilities need pulse response fast enough to match repetition rates of the source. Additionally, neutrino endpoint experiments such as HOLMES need enormous statistics, yet are extremely sensitive to pile-up effects that can distort spectra. These issues can be mitigated only by fast rising and falling edges. To address these needs, we have designed high-speed TES detectors with novel geometric enhancements to increase the thermal conductance of pixels suspended on silicon nitride membranes. This paper shows that the thermal conductivity can be precisely engineered to values spanning over an order of magnitude to achieve fast thermal relaxation times tailored to the relevant applications. Using these pixel prototypes, we demonstrate decay time constants faster than 100 $$\mu $$μs, while still maintaining spectral resolution of 3 eV FWHM at 1.5 keV. This paper also discusses the trade-offs inherent in reducing the pixel time constant, such as increased bias current leading to degradation in energy resolution, and potential modifications to improve performance.

[1]  W. B. Doriese,et al.  Transition-Edge Sensor Microcalorimeters for X-ray Beamline Science , 2014 .

[2]  Joseph W. Fowler,et al.  High-resolution gamma-ray spectroscopy with a microwave-multiplexed transition-edge sensor array , 2013, 1310.7287.

[3]  Kent D. Irwin,et al.  Transition-Edge Sensors , 2005 .

[4]  Clarke,et al.  Hot-electron effects in metals. , 1994, Physical review. B, Condensed matter.

[5]  Joel N. Ullom,et al.  Review of superconducting transition-edge sensors for x-ray and gamma-ray spectroscopy , 2015 .

[6]  K. Blaum,et al.  Direct Measurement of the Mass Difference of $^{163}$Ho and $^{163}$Dy Solves the $Q$-Value Puzzle for the Neutrino Mass Determination , 2015, 1604.04210.

[7]  R. Horansky,et al.  A Two-Fluid Model for the Transition Shape in Transition-Edge Sensors , 2012 .

[8]  A. A. Ocampo Rios,et al.  Search for decays of stopped long-lived particles produced in proton–proton collisions at $$\sqrt{s}= 8\,\text {TeV} $$s=8TeV , 2015, The European physical journal. C, Particles and fields.

[9]  G. C. Hilton,et al.  Developments in Time-Division Multiplexing of X-ray Transition-Edge Sensors , 2016, Journal of low temperature physics.

[10]  J. R. Gao,et al.  Low-noise transition edge sensor (TES) for SAFARI instrument on SPICA , 2010, Astronomical Telescopes + Instrumentation.

[11]  A. Giachero,et al.  Algorithms for Identification of Nearly-Coincident Events in Calorimetric Sensors , 2015, Journal of low temperature physics.

[12]  G. Hilton,et al.  HOLMES: The electron capture decay of 163Ho to measure the electron neutrino mass with sub-eV sensitivity , 2014, 1412.5060.