Development of the low frequency telescope focal plane detector modules for LiteBIRD

B. Westbrook, C. Raum, S. Beckman, Adrian T. Lee, Nicole Farias, Andrew Bogdan, A. Hornsby, A. Suzuki, K. Rotermund, T. Elleflot, Jason E. Austerman, J. Beall, S. Duff, J. Hubmayr, M. Vissers, M. Link, G. Jaehnig, N. Halverson, Tomasso Ghigna, S. Stever, Y. Minami, Keith L. Thompson, Megan B. Russell, K. Arnold, M. Silva-Feaver
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引用次数: 3

Abstract

LiteBIRD is a JAXA-led strategic large-class satellite mission designed to measure the polarization of the cosmic microwave background and Galactic foregrounds from 34 to 448 GHz across the entire sky from L2 in the late 2020s. The scientific payload includes three telescopes which are called the low-, mid-, and high-frequency telescopes each with their own receiver that covers a portion of the mission’s frequency range. The low frequency telescope will map synchrotron radiation from the Galactic foreground and the cosmic microwave background. We discuss the design, fabrication, and characterization of the low-frequency focal plane modules for low-frequency telescope, which has a total bandwidth ranging from 34 to 161 GHz. There will be a total of 4 different pixel types with 8 overlapping bands to cover the full frequency range. These modules are housed in a single low-frequency focal plane unit which provides thermal isolation, mechanical support, and radiative baffling for the detectors. The module design implements multi-chroic lenslet-coupled sinuous antenna arrays coupled to transition edge sensor bolometers read out with frequency-domain mulitplexing. While this technology has strong heritage in ground-based cosmic microwave background experiments, the broad frequency coverage, low optical loading conditions, and the high cosmic ray background of the space environment require further development of this technology to be suitable for LiteBIRD. In these proceedings, we discuss the optical and bolometeric characterization of a triplexing prototype pixel with bands centered on 78, 100, and 140 GHz.
LiteBIRD低频望远镜焦平面探测模块的研制
LiteBIRD是jaxa领导的一项战略大型卫星任务,旨在测量宇宙微波背景和银河前景的极化,从20世纪20年代末开始,从L2到整个天空的34到448 GHz。科学有效载荷包括三个望远镜,分别被称为低、中、高频望远镜,每个望远镜都有自己的接收器,覆盖任务频率范围的一部分。低频望远镜将绘制来自银河系前景和宇宙微波背景的同步辐射图。讨论了总带宽为34 ~ 161ghz的低频望远镜用低频焦平面模块的设计、制造和特性。总共将有4种不同的像素类型,8个重叠的波段覆盖整个频率范围。这些模块被安置在一个单一的低频焦平面单元中,为探测器提供热隔离、机械支持和辐射挡板。该模块设计实现了多频透镜耦合的正弦天线阵列,该阵列耦合到以频域多路复用读出的过渡边缘传感器辐射热计。虽然该技术在地面宇宙微波背景实验中具有很强的继承性,但由于空间环境的频率覆盖范围广、光负载条件低、宇宙射线背景高,需要进一步发展该技术以适应LiteBIRD。在本论文中,我们讨论了以78 GHz、100 GHz和140 GHz为中心的三路复用原型像素的光学和测热特性。
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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