Phases in HfO2‑Based Ferroelectric Thin Films and Their Integration in Low-Power Devices

Pavan Pujar; Haewon Cho; Sunkook Kim

doi:10.1021/ACSAELM.2C01513

Phases in HfO₂‑Based Ferroelectric Thin Films and Their Integration in Low-Power Devices

Pavan Pujar, Haewon Cho, Sunkook Kim

Department of Advanced Materials Science and Engineering

Sungkyunkwan University

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

HfO₂-based ferroelectrics are applied in a large spectrum of electronic devices ranging from ultralow-power logic to nonvolatile memory. The efficacy of these ferroelectrics is that these offer complementary metal oxide semiconductor compatibility in conjunction with large coercive fields and ferroelectricity at sub-10 nm thicknesses. Because of these advantages compared with conventional lead-based thick perovskite films (>50 nm), the present spotlight article focuses on their use to surpass the physical limit of the subthreshold swing (60 mV/dec at room temperature) of field-effect transistors (FETs) via the stabilization of the negative capacitance. In addition, the discussion on HfO₂-ferroelectric-based memories is focused on two-terminal random-access devices, tunnel junctions, three-terminal ferroelectric FETs and their respective 3D stacked architectures.(Figure Presented).

Original language	English
Pages (from-to)	11-20
Number of pages	10
Journal	ACS Applied Electronic Materials
Volume	5
Issue number	1
DOIs	https://doi.org/10.1021/ACSAELM.2C01513
State	Published - 24 Jan 2023

Keywords

ferroelectrics
field-effect transistors
HfO
memories
negative capacitance

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10.1021/ACSAELM.2C01513

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abstract = "HfO2-based ferroelectrics are applied in a large spectrum of electronic devices ranging from ultralow-power logic to nonvolatile memory. The efficacy of these ferroelectrics is that these offer complementary metal oxide semiconductor compatibility in conjunction with large coercive fields and ferroelectricity at sub-10 nm thicknesses. Because of these advantages compared with conventional lead-based thick perovskite films (>50 nm), the present spotlight article focuses on their use to surpass the physical limit of the subthreshold swing (60 mV/dec at room temperature) of field-effect transistors (FETs) via the stabilization of the negative capacitance. In addition, the discussion on HfO2-ferroelectric-based memories is focused on two-terminal random-access devices, tunnel junctions, three-terminal ferroelectric FETs and their respective 3D stacked architectures.(Figure Presented).",

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T1 - Phases in HfO2‑Based Ferroelectric Thin Films and Their Integration in Low-Power Devices

AU - Pujar, Pavan

AU - Cho, Haewon

AU - Kim, Sunkook

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Y1 - 2023/1/24

N2 - HfO2-based ferroelectrics are applied in a large spectrum of electronic devices ranging from ultralow-power logic to nonvolatile memory. The efficacy of these ferroelectrics is that these offer complementary metal oxide semiconductor compatibility in conjunction with large coercive fields and ferroelectricity at sub-10 nm thicknesses. Because of these advantages compared with conventional lead-based thick perovskite films (>50 nm), the present spotlight article focuses on their use to surpass the physical limit of the subthreshold swing (60 mV/dec at room temperature) of field-effect transistors (FETs) via the stabilization of the negative capacitance. In addition, the discussion on HfO2-ferroelectric-based memories is focused on two-terminal random-access devices, tunnel junctions, three-terminal ferroelectric FETs and their respective 3D stacked architectures.(Figure Presented).

AB - HfO2-based ferroelectrics are applied in a large spectrum of electronic devices ranging from ultralow-power logic to nonvolatile memory. The efficacy of these ferroelectrics is that these offer complementary metal oxide semiconductor compatibility in conjunction with large coercive fields and ferroelectricity at sub-10 nm thicknesses. Because of these advantages compared with conventional lead-based thick perovskite films (>50 nm), the present spotlight article focuses on their use to surpass the physical limit of the subthreshold swing (60 mV/dec at room temperature) of field-effect transistors (FETs) via the stabilization of the negative capacitance. In addition, the discussion on HfO2-ferroelectric-based memories is focused on two-terminal random-access devices, tunnel junctions, three-terminal ferroelectric FETs and their respective 3D stacked architectures.(Figure Presented).

KW - ferroelectrics

KW - field-effect transistors

KW - HfO

KW - memories

KW - negative capacitance

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Phases in HfO₂‑Based Ferroelectric Thin Films and Their Integration in Low-Power Devices

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Keywords

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