Development of SQUID Array Amplifiers for the LiteBIRD CMB Satellite

TL;DR

This paper discusses the development and optimization of single-stage SQUID array amplifiers for the LiteBIRD satellite's cosmic microwave background measurements, focusing on meeting strict performance and power requirements.

Contribution

It presents the design and simulation of optimized single-stage SQUID array amplifiers tailored for LiteBIRD's specific needs, demonstrating feasible performance within constraints.

Findings

Optimized SQUID damping and loading improve performance.

Simulations show meeting low noise and power requirements.

Design provides engineering margin for LiteBIRD.

Abstract

LiteBIRD is an upcoming JAXA-led mission that aims to measure primordial gravitational waves in the B-mode polarization of the cosmic microwave background. It is set to launch in 2032. The LiteBIRD detector array consists of around 5000 TES detectors which are read out using digital frequency multiplexing over a bandwidth of 1-6 MHz. The multiplexing factor ranges from 58x to 68x. We are presently developing single-stage SQUID array amplifiers for LiteBIRD readout. Due to the reduced complexity and cost, and greater heritage from ground-based experiments such as the South Pole Telescope and Simons Array, single-stage SQUID array amplification is preferable for the first-stage amplification, as long as it can meet the requirements. The LiteBIRD single-stage SQUID Array is required to have high transimpedance amplification while maintaining a low input inductance and low dynamic resistance. In addition, the input-referred current noise must be very low, and the power dissipation must remain below about 100 nW. These requirements have non-trivial interactions. To maximize performance within these requirements we have performed lumped-element SQUID simulation. We find that by optimizing SQUID internal damping elements and inductive loading, good single-stage SQUID array performance can be obtained for LiteBIRD, including significant engineering margin.