Advanced 3D Integration Technologies in Various Quantum Computing Devices

IF 1.8 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Peng Zhao;Yu Dian Lim;Hong Yu Li;Guidoni Luca;Chuan Seng Tan
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引用次数: 5

Abstract

As a key approach to augment Moore's Law scaling, 3D integration technologies have enabled small form factor, low cost, diverse, modular and flexible assembly of integrated circuits in the semiconductor industry. It is therefore essential to adopt these technologies to the quantum computing devices which are at the nascent stage and generally require large scale integration to be practical. In this review, we focus on four popular quantum bit (qubit) candidates (trapped ion, superconducting circuit, silicon spin and photon) which are encoded by distinct physical systems but all intrinsically compatible with advanced CMOS fabrication process. We introduce the specific scalability bottlenecks of each qubit type and present the current solutions using 3D integration technologies. We evaluate and classify these technologies into three main categories based on the hierarchy. A brief discussion regarding the thermal management is also provided. We believe this review serves to provide some useful insights on the contributions of interconnect, integration and packaging to the field of quantum computing where rapid development is ongoing.
先进的3D集成技术在各种量子计算设备
作为增强摩尔定律缩放的关键方法,3D集成技术使半导体行业集成电路的小尺寸、低成本、多样化、模块化和灵活组装成为可能。因此,将这些技术应用于量子计算设备是至关重要的,因为量子计算设备处于起步阶段,通常需要大规模集成才能实现。在这篇综述中,我们重点介绍了四种常用的量子比特候选(捕获离子、超导电路、硅自旋和光子),它们由不同的物理系统编码,但都与先进的CMOS制造工艺本质上兼容。我们介绍了每种量子比特类型的具体可扩展性瓶颈,并介绍了目前使用3D集成技术的解决方案。我们根据层次结构将这些技术评估和分类为三个主要类别。对热管理进行了简要的讨论。我们相信这篇综述有助于为互连、集成和封装对正在快速发展的量子计算领域的贡献提供一些有用的见解。
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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来源期刊
CiteScore
3.90
自引率
17.60%
发文量
10
审稿时长
12 weeks
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