http://arxiv.org/abs/1801.07920
Optical coupling to a lumped-element kinetic inductance detector (LEKID) via an antenna and transmission line structure enables a compact detector architecture, easily optimised for the required sensitivity and multiplexing performance of future cosmic microwave background (CMB) experiments. Coupling in this way allows multi-chroic, polarisation-sensitive pixels to be realised through planar on-chip filtering structures. However, adding the necessary dielectric layers to LEKID structures to form the microstrip-coupled architecture has the potential to increase two level system (TLS) contributions, resulting in excess detector noise. Using a lumped-element resonator enables coupling via a microstrip to the inductive section only, whilst leaving capacitive elements clear of potentially noisy dielectrics. Here we present the preliminary data acquired to demonstrate that a microstrip transmission line structure can be coupled to a LEKID architecture with minimal additional TLS contributions. This is achieved through a simple fabrication process, which allows for the dielectric to be removed from capacitive regions of the LEKID. As a result we have produced resonators with the high quality factors required for large multiplexing ratios; thus highlighting the suitability of the separated KID architecture for future observations of the CMB.
A. Hornsby, P. Barry, S. Doyle, et. al.
Thu, 25 Jan 18
40/67
Comments: Presented at the 17th International Workshop on Low Temperature Detectors. Submitted to Journal of Low Temperature Physics
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