Bibcode
Beyer, A. D.; Kenyon, M. E.; Echternach, P. M.; Eom, B.-H.; Bueno, J.; Day, P. K.; Bock, J. J.; Bradford, C. M.
Referencia bibliográfica
Millimeter, Submillimeter, and Far-Infrared Detectors and Instrumentation for Astronomy V. Edited by Holland, Wayne S.; Zmuidzinas, Jonas. Proceedings of the SPIE, Volume 7741, pp. 774121-774121-10 (2010).
Fecha de publicación:
7
2010
Número de citas
0
Número de citas referidas
0
Descripción
We report on the characterization of SixNy (Si-N) optical absorbers and
support beams for transition-edge sensors (TESs). The absorbers and
support beams measured are suitable to meet ultra-sensitive noise
equivalent power (NEP<=10-19W/√Hz) and effective
response time (τ) requirements (τ<=100ms) for space-borne
far-infrared( IR)/submillimeter(sub-mm) spectrometers, such as the
Background Limited far-Infrared/Sub-mm Spectrograph (BLISS) and the
SpicA FAR-infrared Instrument (SAFARI) for the SPace Infrared telescope
for Cosmology and Astrophysics (SPICA). The thermal response time
(τ0) of an absorber suspended by support beams from a lowtemperature
substrate depends on the heat capacity (C) of the absorber and the
thermal conductance (G) of the support beams (τ0=C/G). In
membrane-isolated TESs for BLISS, the effective response time τ is
expected to be a factor of 20 smaller than τ0 because of
voltage-biased electrothermal feedback operation and assumption of a
reasonable open-loop gain, LI~20. We present design specifications for
the arrays of membrane-isolated ultra-sensitive TESs for BLISS.
Additionally, we measured G and τ0 for two Si-N noise thermometry
device (NTD) architectures made using different fabrication processes:
(1) a solid membrane Si-N absorber suspended by thin and long Si-N
support beams and (2) a wire-mesh Si-N absorber suspended by long, and
even thinner, Si-N support beams. The measurements of G and τ0 were
designed to test suitability of the Si-N thermal performance to meet the
demands of the two SPICA instruments. The solid membrane NTD
architecture is similar to the TES architecture for SAFARI and the mesh
membrane NTD is similar to that of BLISS TESs. We report measured values
of G and C for several BLISS and SAFARI NTD devices. We observe that the
heat capacity of the solid membrane devices can be reduced to the order
of 1fJ/K at 65mK for devices that are wet etched by KOH. However, C for
these devices is found to be on the order of 100fJ/K for a dry XeF2
process. The heat capacity is similarly large for the mesh devices
produced with a dry XeF2 etch.