Title :
AC biased TES-based X-ray microcalorimeter with an energy resolution of 6.3 eV at 5.89 keV
Author :
van der Kuur, J. ; de Korte, P.A.J. ; Hoevers, H.F.C. ; Tiest, W. M Bergmann ; Baars, N.H.R. ; Ridder, M.L. ; Krouwer, E. ; Bruijn, M.P. ; Kiviranta, M. ; Seppa, H.
Author_Institution :
SRON Nat. Inst. for Space Res., Utrecht, Netherlands
fDate :
6/1/2003 12:00:00 AM
Abstract :
Frequency domain multiplexing (FDM) is an attractive option for the readout of imaging arrays of microcalorimeters. The most straightforward implementation of FDM is based on alternating voltage (AC) biasing of the individual microcalorimeters. It is clear that for future applications the performance in terms of energy resolution and count rate capability is crucial. We discuss the consequences of AC bias for the performance of a microcalorimeter, and make a direct experimental comparison between the performance of a TES based microcalorimeter AC and DC bias. Modeling, as well as experiments, show that the performance of the device is is very similar in terms of energy resolution and pulse shapes (100 μs effective time constant). The measured energy resolution at 5.89 keV photon energy is 6.3 eV for AC bias at 46 kHz and 5.5 eV for DC bias.
Keywords :
X-ray detection; X-ray imaging; frequency division multiplexing; particle calorimetry; readout electronics; superconducting arrays; superconducting particle detectors; 46 kHz; 5.89 keV; AC bias; X-ray microcalorimeter imaging array; count rate; energy resolution; frequency domain multiplexing; pulse shape; readout electronics; superconducting transition edge sensor; Energy resolution; Frequency division multiplexing; Millimeter wave technology; Optical imaging; Pulse amplifiers; SQUIDs; Temperature sensors; Thermal conductivity; Thermal resistance; X-ray imaging;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2003.813980
