RF Characterization on Nb-based Superconducting Silicon Interconnect Fabric for Future Large Scale Quantum Applications

2022 IEEE 72nd Electronic Components and Technology Conference (ECTC) Pub Date : 2022-05-01 DOI:10.1109/ectc51906.2022.00154

Yu-Tao Yang, Haoxiang Ren, S. Chong, Gang Qiu, Shu-Yun Ku, Yang Cheng, Chaowei Hu, Tiema Qian, Kuan-Neng Chen, Ni Ni, Kang L. Wang, S. Iyer

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Abstract

To preserve delicate quantum signals (few hundreds to a few tens of µV), low-loss and low-crosstalk inter-dielet communication is a must in a wafer-scale integrated quantum system using Superconducting-IF. In this paper, inter-dielet links (short: 125 μm and 500 μm; long: 1750 μm) with L/S (2/2 and 5/5 μm) are characterized in a broadband 20 GHz range through simulation and experiments at 4K A compact assembly (inter-dielet spacing of 100 μm) through the quantum-compatible fine-pitch (10 um) Au interlayer is conducted. For insertion loss and crosstalk characterization, the simulated and measured results are presented to be low-loss (<1 dB) and low-crosstalk (< -23 dB) in the broadband 20 GHz range with short (≤ 500 um) and long (1750 um) links and two L/S (2/2 and 5/5 um). It is one of the first 20 GHz broadband RF characterization of short superconducting links (≤ 500 um) through advanced packaging for cryogenic inter-dielet quantum communication. This work brings large-scale quantum computing closer to being realized through compact heterogeneous integration.

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面向未来大规模量子应用的铌基超导硅互连结构的射频特性研究

为了保持微妙的量子信号(几百到几十µV)，在使用超导中频的晶圆级集成量子系统中，低损耗和低串扰的介子间通信是必须的。在本文中，介子间链路(短:125 μm和500 μm;通过在4K条件下的模拟和实验，对长1750 μm、L/S(2/2和5/5 μm)的光纤在宽带20 GHz范围内的特性进行了表征。对于插入损耗和串扰特性，模拟和测量结果表明，在宽带20ghz范围内，具有短(≤500 um)和长(1750 um)链路和两个L/S(2/2和5/5 um)，低损耗(<1 dB)和低串扰(< -23 dB)。这是第一个通过先进封装实现低温介子间量子通信的短超导链路(≤500 um)的20 GHz宽带RF表征之一。这项工作使大规模量子计算更接近于通过紧凑的异构集成实现。

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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2022 IEEE 72nd Electronic Components and Technology Conference (ECTC)

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