CCAT: Nonlinear effects in 280 GHz aluminum kinetic inductance detectors

arXiv - PHYS - Instrumentation and Methods for Astrophysics Pub Date : 2024-09-03 DOI:arxiv-2409.02271

Cody J. Duell, Jason Austermann, James R. Burgoyne, Scott C. Chapman, Steve K. Choi, Abigail T. Crites, Rodrigo G. Freundt, Anthony I. Huber, Zachary B. Huber, Johannes Hubmayr, Ben Keller, Lawrence T. Lin, Alicia M. Middleton, Colin C. Murphy, Michael D. Niemack, Thomas Nikola, Darshan Patel, Adrian K. Sinclair, Ema Smith, Gordon J. Stacey, Anna Vaskuri, Eve M. Vavagiakis, Michael Vissers, Samantha Walker, Jordan Wheeler

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Abstract

Prime-Cam, a first-generation science instrument for the Atacama-based Fred Young Submillimeter Telescope, is being built by the CCAT Collaboration to observe at millimeter and submillimeter wavelengths using kinetic inductance detectors (KIDs). Prime-Cam's 280 GHz instrument module will deploy with two aluminum-based KID arrays and one titanium nitride-based KID array, totaling approximately 10,000 detectors at the focal plane, all of which have been fabricated and are currently undergoing testing. One complication of fielding large arrays of KIDs under dynamic loading conditions is tuning the detector tone powers to maximize signal-to-noise while avoiding bifurcation due to the nonlinear kinetic inductance. For aluminum-based KIDs, this is further complicated by additional nonlinear effects which couple tone power to resonator quality factors and resonant frequencies. While both nonequilibrium quasiparticle dynamics and two-level system fluctuations have been shown to give rise to qualitatively similar distortions, modeling these effects alongside nonlinear kinetic inductance is inefficient when fitting thousands of resonators on-sky with existing models. For this reason, it is necessary to have a detailed understanding of the nonlinear effects across relevant detector loading conditions, including how they impact on on-sky noise and how to diagnose the detector's relative performance. We present a study of the competing nonlinearities seen in Prime-Cam's 280 GHz aluminum KIDs, with a particular emphasis on the resulting distortions to the resonator line shape and how these impact detector parameter estimation.

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CCAT：280 GHz 铝动感探测器中的非线性效应

Prime-Cam是阿塔卡马弗雷德-杨亚毫米波望远镜的第一代科学仪器，由CCAT合作组织建造，利用动能感应探测器（KID）在毫米和亚毫米波段进行观测。Prime-Cam 的 280 GHz 仪器模块将部署两个铝基 KID 阵列和一个氮化钛基 KID 阵列，焦平面上总共约有 10,000 个探测器，所有这些探测器都已制造完成，目前正在进行测试。在动态加载条件下现场使用大型 KID 阵列的一个复杂问题是调整探测器功率，以最大限度地提高信噪比，同时避免因非线性动感而产生分叉。对于铝基 KID 而言，额外的非线性效应会将音调功率与谐振器品质因数和谐振频率耦合在一起，从而使问题进一步复杂化。虽然非平衡态等离子体动力学和两级系统波动已被证明会引起本质上相似的畸变，但在用现有模型拟合数千个天空谐振器时，将这些效应与非线性动感一起建模的效率很低。因此，有必要详细了解相关探测器加载条件下的非线性效应，包括它们对天空噪声的影响，以及如何诊断探测器的相对性能。我们对 Prime-Cam 的 280 GHz 铝质 KID 中出现的竞争性非线性效应进行了研究，特别强调了由此产生的谐振线形状失真，以及这些失真如何影响探测器参数估计。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Instrumentation and Methods for Astrophysics

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