Alicia Middleton;Steve K. Choi;Samantha Walker;Jason Austermann;James R. Burgoyne;Victoria Butler;Scott C. Chapman;Abigail T. Crites;Cody J. Duell;Rodrigo G. Freundt;Anthony I. Huber;Zachary B. Huber;Johannes Hubmayr;Ben Keller;Lawrence T. Lin;Michael D. Niemack;Darshan Patel;Adrian K. Sinclair;Ema Smith;Anna Vaskuri;Eve M. Vavagiakis;Michael Vissers;Yuhan Wang;Jordan Wheeler
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引用次数: 0
摘要
Prime-Cam是由CCAT合作开发的弗雷德·杨亚毫米望远镜(FYST)的主要仪器之一,将容纳多达7个仪器模块,第一个工作在280 GHz。每个模块将包括三组超导微波动力学电感探测器(KIDs)。为280 GHz模块制造的第一个KID阵列使用氮化钛(TiN)作为超导材料,具有3,456个单独的探测器,而其他两个阵列使用铝。本文介绍了280 GHz TiN阵列的设计和实验室特性,该阵列在其临界温度以下冷却至0.1K,并通过6条射频馈线读出。LED映射是一种将探测器的测量谐振频率与其物理位置相匹配的技术,该技术可以在阵列上进行,因此结果可以用于光刻修整KID电容器,并通过减少频率碰撞来提高阵列的良率。我们介绍了在FYST上部署前LED映射280 GHz TiN KID阵列的方法和结果。
CCAT: LED Mapping and Characterization of the 280 GHz TiN KID Array
Prime-Cam, one of the primary instruments for the Fred Young Submillimeter Telescope (FYST) developed by the CCAT Collaboration, will house up to seven instrument modules, with the first operating at 280 GHz. Each module will include three arrays of superconducting microwave kinetic inductance detectors (KIDs). The first KID array fabricated for the 280 GHz module uses titanium-nitride (TiN) as the superconducting material and has 3,456 individual detectors, while the other two arrays use aluminum. This paper presents the design and laboratory characterization of the 280 GHz TiN array, which is cooled below its critical temperature to
$\sim$
0.1K and read out over six RF feedlines. LED mapping, a technique for matching the measured resonant frequency of a detector to its physical position, was performed on the array so that the results can be used to lithographically trim the KID capacitors and increase the yield of the array by reducing frequency collisions. We present the methods and results of LED mapping the 280 GHz TiN KID array before deployment on FYST.
期刊介绍:
IEEE Transactions on Applied Superconductivity (TAS) contains articles on the applications of superconductivity and other relevant technology. Electronic applications include analog and digital circuits employing thin films and active devices such as Josephson junctions. Large scale applications include magnets for power applications such as motors and generators, for magnetic resonance, for accelerators, and cable applications such as power transmission.
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