Mu3e实验的力学、读数和冷却系统

Proceedings of The 28th International Workshop on Vertex Detectors — PoS(Vertex2019) Pub Date : 2020-03-24 DOI:10.22323/1.373.0041

F. M. Aeschbacher, Marin Deflorin, L. Noehte

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引用次数: 5

摘要

Mu3e是Paul Scherrer研究所即将进行的一项实验，旨在寻找$\mu\rightarrow eee$的强烈抑制衰变。它将使用超薄HV-CMOS MAPS芯片的超轻型硅像素探测器。通过使用高密度铝互连和在氦气氛中操作探测器，进一步控制了多重库仑散射。超过1平方米的仪表表面将产生约3.3千瓦的热量($\leq$ 250兆瓦/平方厘米)。传统的冷却方法与低质量要求相冲突，因此将采用气态氦流冷却系统。本报告将报告在现实条件下，使用铝互连器以1.25 Gbit/s的目标速度成功进行数据传输测试。氦气冷却的最终概念验证已经通过全面的冷却模拟实现，并成功地通过使用顶点像素探测器的全尺寸模型的实验室测量进行了验证。

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Mechanics, readout and cooling systems of the Mu3e experiment

Mu3e is an upcoming experiment at Paul Scherrer Institut in the search for the strongly suppressed decay of $\mu\rightarrow eee$. It will use an ultra-lightweight silicon pixel detector using thinned HV-CMOS MAPS chips. Multiple Coulomb scattering is further kept under control with using high density interconnects made of aluminium and operating the detector in a helium atmosphere. More than 1 m2 of instrumented surface will produce about 3.3 kW of heat ($\leq$ 250 mW/cm2). Traditional cooling approaches are in conflict with the low-mass requirements, hence a gaseous helium flow cooling system will be implemented. This talk will give a report on the successful data transmission tests with the aluminium interconnects at target speeds of 1.25 Gbit/s under realistic condition. The final proof-of-concept of the helium cooling has been achieved with comprehensive cooling simulations and successfully confirmed with laboratory measurements using a full-scale mock-up of the vertex pixel detector.

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Proceedings of The 28th International Workshop on Vertex Detectors — PoS(Vertex2019)

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