3D interconnects for III-V semiconductor heterostructures for miniaturized power devices

IF 7.9 2区综合性期刊 Q1 CHEMISTRY, MULTIDISCIPLINARY

Cell Reports Physical Science Pub Date : 2023-11-22 DOI:10.1016/j.xcrp.2023.101701

Mathieu de Lafontaine, Thomas Bidaud, Guillaume Gay, Erwine Pargon, Camille Petit-Etienne, Artur Turala, Romain Stricher, Serge Ecoffey, Maïté Volatier, Abdelatif Jaouad, Christopher E. Valdivia, Karin Hinzer, Simon Fafard, Vincent Aimez, Maxime Darnon

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Abstract

Three-dimensional (3D) interconnects increase chip power density and enable miniaturization. Photonic chips require new processes to enable transitioning to 3D interconnects. We fabricate 3D interconnects on a multijunction solar cell, leveraging processes such as III-V heterostructure plasma etching, gold electrodeposition, and chemical-mechanical polishing to integrate through substrate vias to the heterostructure. Wafer bonding is used to handle 20-μm-thin III-V films. The strategy enables us to demonstrate photonic power devices having areas 3 orders of magnitude smaller compared to standard chips. The design also yields a small shading factor below 3%. Compared to miniaturized photonic power devices with two-dimensional connections, 3D interconnects achieve a 6-fold increase in wafer area use. These improvements will enhance the power yield per wafer while unlocking high-density and miniaturized devices for applications such as power over fiber, the internet of things, and microconcentrator photovoltaics.

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用于小型化功率器件的III-V型半导体异质结构的三维互连

三维(3D)互连可提高芯片功率密度并实现小型化。光子芯片需要新的工艺来实现向3D互连的过渡。我们在多结太阳能电池上制造3D互连，利用III-V异质结构等离子体蚀刻，金电沉积和化学机械抛光等工艺，通过衬底通孔集成到异质结构上。晶圆键合用于处理20 μm薄的III-V薄膜。该策略使我们能够展示光子功率器件的面积比标准芯片小3个数量级。该设计还产生了一个小的遮阳系数低于3%。与具有二维连接的小型化光子功率器件相比，3D互连实现了晶圆面积使用的6倍增长。这些改进将提高每片晶圆的功率产量，同时为光纤供电、物联网和微聚光器光伏等应用解锁高密度和小型化设备。

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来源期刊

Cell Reports Physical Science Energy-Energy (all)

CiteScore

11.40

自引率

2.20%

发文量

388

审稿时长

62 days

期刊介绍： Cell Reports Physical Science, a premium open-access journal from Cell Press, features high-quality, cutting-edge research spanning the physical sciences. It serves as an open forum fostering collaboration among physical scientists while championing open science principles. Published works must signify significant advancements in fundamental insight or technological applications within fields such as chemistry, physics, materials science, energy science, engineering, and related interdisciplinary studies. In addition to longer articles, the journal considers impactful short-form reports and short reviews covering recent literature in emerging fields. Continually adapting to the evolving open science landscape, the journal reviews its policies to align with community consensus and best practices.