Low Temperature and Ion-Cut Based Monolithic 3D Process Integration Platform Incorporated with CMOS, RRAM and Photo-Sensor Circuits

2020 IEEE International Electron Devices Meeting (IEDM) Pub Date : 2020-12-12 DOI:10.1109/IEDM13553.2020.9372102

Hoonhee Han, R. Choi, Seong-ook Jung, S. Chung, B. Cho, S. C. Song, C. Choi

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引用次数: 3

Abstract

We demonstrated low temperature (< 500 °C) and hydrogen ion-cut based monolithic 3D (M3D) process integration platform with CMOS circuits, memory devices and photo-sensitive sensors. Top Si layer was transferred on the 8-inch bottom Si substrate having standard CMOS circuits using hydrogen ion implantation, bonding and cleavage under low thermal annealing. Ta2O5-RRAM and a-IGZO photo detector devices on the upper transferred Si layer were vertically stacked with CMOS circuits. Bonding and top Si layer transfer are considerably affected by ion implantation process, ILD, surface treatment, oxide CMP and annealing. Different light intensity to photodetector at the upper layer modulates the frequency of current sensor with 21 stage ring- oscillator at the lower layer and current level in RRAM at the upper layer is also modulated by input frequency from CMOS devices. The functionalities of ion-cut based M3D integration platform are confirmed by higher frequency and current level with respect to light intensity.

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基于低温和离子切割的单片3D工艺集成平台，集成了CMOS, RRAM和光传感器电路

我们展示了低温(< 500°C)和基于氢离子切割的单片3D (M3D)工艺集成平台，该平台具有CMOS电路，存储器件和光敏传感器。采用氢离子注入、低温退火键合和解理的方法，将顶部硅层转移到具有标准CMOS电路的8英寸底部硅衬底上。上层转移Si层的Ta2O5-RRAM和a-IGZO光电探测器器件与CMOS电路垂直堆叠。离子注入工艺、ILD、表面处理、氧化物CMP和退火对键合和顶部Si层转移有很大影响。上层光电探测器的不同光强调制下层21级环形振荡器电流传感器的频率，上层RRAM中的电流电平也由CMOS器件的输入频率调制。基于离子切割的M3D集成平台的功能通过相对于光强的更高频率和电流水平得到证实。

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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2020 IEEE International Electron Devices Meeting (IEDM)

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