Frequency Domain Multiplexing: Reading Microsecond TES Signals

by Anika Shah - Technology
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Summary of the New Readout System for Neutrinoless Double-Beta Decay Experiments

This text details a notable advancement in readout technology for cryogenic calorimeters used in the search for neutrinoless double-beta decay, specifically geared towards experiments like CUPID. Here’s a breakdown of the key points:

Problem: Current experiments rely on NTD thermistors which are slow (1ms response time), limiting background discrimination and sensitivity. A major background source is timing pileup from the 2νββ decay of 100Mo.

Solution: A new readout system utilizing Transition-edge Sensors (TES) and Frequency-Domain Multiplexing (fMux).

Key Features & benefits:

* Speed: Sampling rate of 156kHz – three orders of magnitude faster than previous systems. TES detectors have a response time of 100μs compared to 1ms for ntds.
* Technology: Uses ten superconducting resonators, a SQUID, and FPGA electronics.
* Multiplexing: Achieves a multiplexing factor of 10-15,suitable for CUPID and scalable to tonne-scale experiments.
* Background Reduction: Faster timing allows for better rejection of pileup events,possibly reducing background by up to 50% in the CUPID experiment.
* Scalability: Designed for large-scale calorimeters with thousands of channels, minimizing thermal load and radioactive contamination.
* Adaptability: Resonant circuits are designed to handle fast scintillation light signals expected in CUPID.
* Minimal Material: Cabling is optimized to minimize material near the detectors.

Impact:

* Improved Sensitivity: This system offers a viable pathway to significantly enhance the sensitivity of future neutrinoless double-beta decay experiments.
* Advancement in TES Technology: Demonstrates the potential of TES detectors in rare event searches.

Future Work:

* Scaling up the system to accommodate thousands of channels.
* Refining digital signal processing algorithms.

In essence, this new readout system represents a crucial step forward in the quest to understand the nature of neutrinos and potentially discover the elusive neutrinoless double-beta decay. It addresses a key limitation of current technology and paves the way for more sensitive and precise experiments.

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