Simons Observatory Microwave SQUID Multiplexing Readout: Cryogenic RF Amplifier and Coaxial Chain Design

Mayuri Sathyanarayana Rao,Heather Mccarrick,Michael D Niemack,Ningfeng Zhu,Sara M Simon,Jason R Stevens,Benjamin Westbrook,Trevor Sasse,Jenna Moore,Peter Ashton,Adrian T Lee,Cody J Duell,Maria Salatino,Justin Mathewson,Jonathan Hoh,Eve M Vavagiakis,Joseph Seibert,Christopher Raum,Nicholas Galitzki,Erin Healy,Aashrita Mangu,Maximiliano Silva-Feaver,Aamir Ali,Anna M Kofman,Shannon M Duff,Zhilei Xu,Shuay-Pwu Patty Ho,Robert J Thornton ,Joel N Ullom ,Philip Daniel Mauskopf ,S Henderson ,G P Teply ,A Kusaka ,Bradley Dober ,Suzanne T Staggs ,K Arnold

doi:10.1007/s10909-020-02429-y

Abstract

The Simons Observatory (SO) is an upcoming polarization-sensitive Cosmic Microwave Background (CMB) experiment on the Cerro Toco Plateau (Chile) with large overlap with other optical and infrared surveys (e.g., DESI, LSST, HSC). To enable the readout of \bigO(10,000) detectors in each of the four telescopes of SO, we will employ the microwave SQUID multiplexing technology. With a targeted multiplexing factor of \bigO{(1,000)}, microwave SQUID multiplexing has never been deployed on the scale needed for SO. Here we present the design of the cryogenic coaxial cable and RF component chain that connects room temperature readout electronics to superconducting resonators that are coupled to Transition Edge Sensor bolometers operating at sub-Kelvin temperatures. We describe design considerations including cryogenic RF component selection, system linearity, noise, and thermal power dissipation.

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