TJ-Monopix2 DMAPS在180 nm CMOS技术下的电荷收集和效率测量

Proceedings of 10th International Workshop on Semiconductor Pixel Detectors for Particles and Imaging — PoS(Pixel2022) Pub Date : 2023-01-31 DOI:10.22323/1.420.0080

C. Bespin, I. Caicedo, J. Dingfelder, T. Hemperek, T. Hirono, F. Hugging, H. Kruger, K. Moustakas, H. Pernegger, P. Riedler, L. Schall, W. Snoeys, N. Wermes

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引用次数: 0

摘要

单片CMOS像素探测器已成为高能粒子物理探测器领域的有力竞争者。通过利用商业流程，他们提供了这种探测器的大批量生产。在180美元/ $nm的塔式工艺中设计了一系列原型，耗尽了传感器材料和柱漏读出架构。最新的迭代TJ-Monopix2具有一个大的2$\，$cm x2 $\，$cm矩阵，由512 x 512像素组成，间距为33.04$\，$um。小型收集电极设计以低功耗和低噪声为目标，而高能粒子探测器应用的辐射容限需要特别注意。水平目标达到辐射宽容的10美元^{15}\,1 \ $兆电子伏n $ _ {eq} \ \文本,$厘米$ ^ {2}NIEL损害美元修改标准的过程已经实现了通过添加低剂量的n型硅植入整个像素传感器为了允许均匀损耗的体积。最近对未辐照模块进行了实验室测量和光束测试，以研究电特性和命中检测效率。

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Charge collection and efficiency measurements of the TJ-Monopix2 DMAPS in 180 nm CMOS technology

Monolithic CMOS pixel detectors have emerged as competitive contenders in the field of high-energy particle physics detectors. By utilizing commercial processes they offer high-volume production of such detectors. A series of prototypes has been designed in a 180$\,$nm Tower process with depletion of the sensor material and a column-drain readout architecture. The latest iteration, TJ-Monopix2, features a large 2$\,$cm x 2$\,$cm matrix consisting of 512 x 512 pixels with 33.04$\,$um pitch. A small collection electrode design aims at low power consumption and low noise while the radiation tolerance for high-energy particle detector applications needs extra attention. With a goal to reach radiation tolerance to levels of $10^{15}\,1\,$MeV n$_\text{eq}\,$cm$^{-2}$ of NIEL damage a modification of the standard process has been implemented by adding a low-dosed n-type silicon implant across the pixel in order to allow for homogeneous depletion of the sensor volume. Recent lab measurements and beam tests were conducted for unirradiated modules to study electrical characteristics and hit detection efficiency.

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Proceedings of 10th International Workshop on Semiconductor Pixel Detectors for Particles and Imaging — PoS(Pixel2022)

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