Enhanced ferroelectricity in ultrathin films grown directly on silicon

被引：0

作者：

Suraj S. Cheema

Daewoong Kwon

Nirmaan Shanker

Roberto dos Reis

Shang-Lin Hsu

Jun Xiao

Haigang Zhang

Ryan Wagner

Adhiraj Datar

Margaret R. McCarter

Claudy R. Serrao

Ajay K. Yadav

Golnaz Karbasian

Cheng-Hsiang Hsu

Ava J. Tan

Li-Chen Wang

Vishal Thakare

Xiang Zhang

Apurva Mehta

Evguenia Karapetrova

Rajesh V Chopdekar

Padraic Shafer

Elke Arenholz

Chenming Hu

Roger Proksch

Ramamoorthy Ramesh

Jim Ciston

Sayeef Salahuddin

机构：

[1] University of California,Department of Materials Science and Engineering

[2] University of California,Department of Electrical Engineering and Computer Sciences

[3] Lawrence Berkeley National Laboratory,National Center for Electron Microscopy, Molecular Foundry

[4] University of California,Nanoscale Science and Engineering Center

[5] Oxford Instruments,Asylum Research

[6] University of California,Department of Physics

[7] Berkeley,Materials Sciences Division

[8] Lawrence Berkeley National Laboratory,Stanford Synchrotron Radiation Lightsource

[9] SLAC National Accelerator Laboratory,Advanced Photon Source

[10] Argonne National Laboratory,Advanced Light Source

[11] Lawrence Berkeley National Laboratory,Cornell High Energy Synchrotron Source

[12] Cornell University,Department of Electrical Engineering

[13] Inha University,undefined

来源：

Nature | 2020年 / 580卷

关键词：

D O I：

暂无

中图分类号：

学科分类号：

摘要：

Ultrathin ferroelectric materials could potentially enable low-power logic and nonvolatile memories1,2. As ferroelectric materials are made thinner, however, the ferroelectricity is usually suppressed. Size effects in ferroelectrics have been thoroughly investigated in perovskite oxides—the archetypal ferroelectric system3. Perovskites, however, have so far proved unsuitable for thickness scaling and integration with modern semiconductor processes4. Here we report ferroelectricity in ultrathin doped hafnium oxide (HfO2), a fluorite-structure oxide grown by atomic layer deposition on silicon. We demonstrate the persistence of inversion symmetry breaking and spontaneous, switchable polarization down to a thickness of one nanometre. Our results indicate not only the absence of a ferroelectric critical thickness but also enhanced polar distortions as film thickness is reduced, unlike in perovskite ferroelectrics. This approach to enhancing ferroelectricity in ultrathin layers could provide a route towards polarization-driven memories and ferroelectric-based advanced transistors. This work shifts the search for the fundamental limits of ferroelectricity to simpler transition-metal oxide systems—that is, from perovskite-derived complex oxides to fluorite-structure binary oxides—in which ‘reverse’ size effects counterintuitively stabilize polar symmetry in the ultrathin regime.

引用

页码：478 / 482

页数：4

共 50 条

[1] Enhanced ferroelectricity in ultrathin films grown directly on silicon
Cheema, Suraj S.
Kwon, Daewoong
Shanker, Nirmaan
dos Reis, Roberto
Hsu, Shang-Lin
Xiao, Jun
Zhang, Haigang
Wagner, Ryan
Datar, Adhiraj
McCarter, Margaret R.
Serrao, Claudy R.
Yadav, Ajay K.
Karbasian, Golnaz
Hsu, Cheng-Hsiang
Tan, Ava J.
Wang, Li-Chen
Thakare, Vishal
Zhang, Xiang
Mehta, Apurva
Karapetrova, Evguenia
Chopdekar, Rajesh, V
Shafer, Padraic
Arenholz, Elke
Hu, Chenming
Proksch, Roger
Ramesh, Ramamoorthy
Ciston, Jim
Salahuddin, Sayeef
NATURE, 2020, 580 (7804) : 478 - +
[2] Publisher Correction: Enhanced ferroelectricity in ultrathin films grown directly on silicon
Suraj S. Cheema
Daewoong Kwon
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Haigang Zhang
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[3] Enhanced ferroelectricity in ultrathin films grown directly on silicon (Expression of Concern of Vol 532, Pg 210, 2016)
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