高灵敏度和宽动态范围的偏振探测器阵列在亚毫米域

L. Rodriguez, A. Adami, A. Aliane, X. de la Broïse, C. Delisle, A. Demonti, D. Desforge, S. Dubos, L. Dussopt, C. Gennet, V. Goudon, O. Gevin, H. Kaya, G. Lasfargues, J. Martignac, X. Navick, A. Poglitsch, V. Révéret, M. Sauvage, T. Tollet, F. Visticot
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引用次数: 0

摘要

被取消的用于宇宙学和天体物理学的空间红外望远镜(SPICA)的主要目标之一是揭示磁场对不同天体物理物体结构影响的证据,例如恒星形成区域的丝状结构。为此,根据ESA、CNES和FOCUS的合同,开发了“仪器级像素”探测器阵列,为空间天文台提供了灵敏、紧凑和易于集成的探测解决方案。磁场影响小颗粒和小分子的光发射或吸收,在接收的电磁信息中印记其极化、度、角度和强度等特征。所研制的探测器的每个像素通过两个正交的偶极子网络吸收辐射。探测器阵列像棋盘一样组织,每个其他像素都有旋转45°的吸收器,以便同时揭示线性斯托克斯参数而没有任何光学损失。自PACS探测器以来,通过电网下背短路方案获得了非常高的吸收效率。为了获得1 attoW/√Hz的目标灵敏度,探测器被冷却到50 mK并连接到上述IC CMOS读出电路。对于每个像素,四个交错的螺旋硅传感器收集吸收器功率。它们被组织成惠斯通电桥结构,允许完全差分输出:总功率和极化不平衡强度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Highly sensitive and wide dynamic range polarimetric detectors arrays in the submillimeter domain
One of the main goals of the canceled Space Infrared Telescope for Cosmology and Astrophysics (SPICA), was to reveal the evidence of the influence of magnetic field in the structuration of different astrophysical objects, as for example the filamentary structure of star-forming regions. For this purpose, “instrument-in-pixel” detector arrays were developed under ESA, CNES and FOCUS contracts, to propose sensitive, compact and easy to integrate detection solutions for a Space Observatory. Magnetic field influences the light emission or absorption of small grains and molecules imprinting its characteristics in the received electromagnetic message in terms of polarization, degree, angle and intensity. Each pixel of the developed detectors absorb the radiation through two orthogonal dipole networks. The detector array is organized like a chessboard with every other pixel having absorbers rotated by 45° in order to unveil simultaneously the linear Stokes parameters without any optical loss. A very large absorption efficiency is obtained, as usual since PACS detectors, by a backshort-under-grid scheme. To obtain the goal sensitivity of 1 attoW/√Hz, detectors are cooled to 50 mK and linked to an Above IC CMOS readout circuit. For each pixel, four interleaved spiral silicon sensors gather the absorber power. They are organized in a Wheatstone bridge configuration that allows fully differential outputs: total power and polarization unbalanced intensity.
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