Reliability of Ferroelectric HfO2-based Memories: From MOS Capacitor to FeFET

2020 Device Research Conference (DRC) Pub Date : 2020-06-01 DOI:10.1109/DRC50226.2020.9135148

A. Tan, Li-Chen Wang, Y. Liao, J. Bae, C. Hu, S. Salahuddin

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引用次数: 5

Abstract

Ferroelectric (FE) FETs as nonvolatile memories have enjoyed a recent resurgence among emerging memory technologies due to the discovery of ferroelectricity in HfO 2 [1] . FE-HfO 2 offers attractive qualities such as CMOS compatibility, fast read/write speed, excellent retention, and scalability [2] . However, as write endurance remains a concern, various techniques have been proposed to improve endurance; among them, popular ones include engineering of the interfacial layer (IL), modulating the FE oxide properties, and changing the gate electrode [ 2 - 5 ]. In this work, we demonstrate for the first time a systematic, reliable, and rapid method to qualitatively predict the FE endurance of prospective gate stack designs prior to running a full FeFET fabrication process. MOSCAPs incorporating FE gate stacks (∼ 4.5 nm) realized via a one-step lithography process on highly doped Si are compared against real endurance results from SOI FeFETs incorporating the same FE oxides. The FeFETs demonstrated in this work boast impressive programmability (0.4 - 0.5V memory window at ±3.3V, 1 µ s) and a strong potential for further scalability.

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基于hfo2的铁电存储器的可靠性:从MOS电容器到ffet

铁电(FE) fet作为非易失性存储器，由于在HfO 2中发现了铁电性[1]，最近在新兴存储技术中重新兴起。FE-HfO 2具有吸引人的特性，如CMOS兼容性、快速读写速度、出色的保留性和可扩展性[2]。然而，由于写入持久性仍然是一个问题，人们提出了各种技术来提高持久性;其中比较流行的有界面层(IL)工程、FE氧化物性质调制、栅极改变等[2 - 5]。在这项工作中，我们首次展示了一种系统、可靠和快速的方法，可以在运行完整的ffet制造过程之前，定性地预测未来栅极堆叠设计的FE耐久性。通过一步光刻工艺在高掺杂Si上实现的含有FE栅极堆(~ 4.5 nm)的MOSCAPs与含有相同FE氧化物的SOI fefet的实际耐用性结果进行了比较。在这项工作中展示的fefet具有令人印象深刻的可编程性(±3.3V, 1µs的0.4 - 0.5V内存窗口)和进一步扩展的强大潜力。

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 Device Research Conference (DRC)

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