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Next Generation Ferroelectric Memories enabled by Hafnium Oxide

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Abstract:

Ferroelectrics are theoretically an ideal solution for low write power nonvolatile memories. However, the complexity of ferroelectric perovskites has hindered the scaling...Show More

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Abstract:

Ferroelectrics are theoretically an ideal solution for low write power nonvolatile memories. However, the complexity of ferroelectric perovskites has hindered the scaling of such devices to competitive feature sizes. The discovery of ferroelectricity in hafnium oxide solved this issue. Ferroelectric memories in three variants, capacitor based ferroelectric RAM, ferroelectric field effect transistors and ferroelectric tunneling junctions have become competitors for future memory solutions again. In this paper, the basics and current status of hafnium oxide based ferroelectric memory devices is described and recent results are shown.

Published in: 2019 IEEE International Electron Devices Meeting (IEDM)

Date of Conference: 07-11 December 2019

Date Added to IEEE Xplore: 13 February 2020

ISBN Information:

ISSN Information:

DOI: 10.1109/IEDM19573.2019.8993447

Conference Location: San Francisco, CA, USA

References is not available for this document.

Contents

I. Introduction

Ferroelectrics are materials that show a remanent polarization that can be switched between two directions using an electrical field. The stable nonvolatile polarization paired with the purely field driven switching, make this class of materials a natural choice for nonvolatile memories overcoming the write inefficiency of most other emerging nonvolatile memory concepts [1]. However, typically the materials that show ferroelectricity have a complex structure with three or more compounds and in the case of oxides normally weakly bound oxygen (see fig. 1 b). These properties make them very hard to integrate into a state of the art CMOS process [2]. As a result, the established ferroelectric memory technologies are limited in scaling and therefore are only used in niche applications. Thus, after an intense phase of research and development between the late 1990s and the mid 2000s, the interest in ferroelectrics for memory applications diminished. The discovery of ferroelectricity in doped hafnium oxide (see fig. 1a) has changed that view since hafnium oxide is used as the gate dielectric in modern transistors since 2007. Traditionally, a 1 transistor – 1 capacitor cell (FeRAM see fig. 2a) inspired by DRAM is used in established ferroelectric memory devices. An alternative way is to integrate the ferroelectric into the gate stack of an MOS transistor (FeFET see fig. 2b). Finally, a resistive switching ferroelectric tunneling junction can be achieved when the ferroelectric is made very thin and allows for a polarization dependent tunneling current (FTJ see fig. 2c). All three memory concepts have seen increased activities by using hafnium oxide based ferroelectrics rather than traditional perovskites or layered perovskites.