Advanced Materials

, volume 27 , issue 11 , pages 1811-1831

Ferroelectricity and antiferroelectricity of doped thin HfO2-based films.

M H Park ^{1, 2}

Younghwan Lee ^{1, 2}

Han-Joon Kim ^{1, 2}

Yu Jin Kim ^{1, 2}

Taehwan Moon ^{1, 2}

Keum Do Kim ^{1, 2}

Johannes Müller ³

A. Kersch ⁴

U. Schroeder ⁵

Thomas Mikolajick ⁵

Cheol Mok Hwang ^{1, 2}

Hide authors affiliations Show authors affiliations: 5 affiliations

Department of Materials Science and Engineering; Seoul National University; Seoul 151-744 Republic of Korea |

Inter-university Semiconductor Research Center; College of EngineeringSeoul National University; Seoul 151-744 Republic of Korea |

Fraunhofer IPMS-CNT; Koenigsbruecker Str. 178 01109 Dresden Germany |

⁴

University of Applied Sciences Munich; Lothstr. 34 80335 Munich Germany |

⁵

NaMLab gGmbH/TU Dresden; Noethnitzer Str. 64 01187 Dresden Germany |

Publication type: Journal Article

Publication date: 2015-02-11

Wiley

Advanced Materials

scimago Q1

wos Q1

SJR: 8.851

CiteScore: 39.4

Impact factor: 26.8

ISSN: 09359648, 15214095

DOI: 10.1002/adma.201404531

Copy DOI

PubMed ID: 25677113

General Materials Science

Mechanical Engineering

Mechanics of Materials

Abstract

The recent progress in ferroelectricity and antiferroelectricity in HfO2-based thin films is reported. Most ferroelectric thin film research focuses on perovskite structure materials, such as Pb(Zr,Ti)O3, BaTiO3, and SrBi2Ta2O9, which are considered to be feasible candidate materials for non-volatile semiconductor memory devices. However, these conventional ferroelectrics suffer from various problems including poor Si-compatibility, environmental issues related to Pb, large physical thickness, low resistance to hydrogen, and small bandgap. In 2011, ferroelectricity in Si-doped HfO2 thin films was first reported. Various dopants, such as Si, Zr, Al, Y, Gd, Sr, and La can induce ferro-electricity or antiferroelectricity in thin HfO2 films. They have large remanent polarization of up to 45 μC cm(-2), and their coercive field (≈1-2 MV cm(-1)) is larger than conventional ferroelectric films by approximately one order of magnitude. Furthermore, they can be extremely thin (<10 nm) and have a large bandgap (>5 eV). These differences are believed to overcome the barriers of conventional ferroelectrics in memory applications, including ferroelectric field-effect-transistors and three-dimensional capacitors. Moreover, the coupling of electric and thermal properties of the antiferroelectric thin films is expected to be useful for various applications, including energy harvesting/storage, solid-state-cooling, and infrared sensors.

Found

13 citations

Markeev Andrey

🥼

DSc in Engineering

109 publications, 3 032 citations, 5 reviews

h-index: 29

Moscow Institute of Physics and Technology

Research interests

Atomic layer deposition

Ferroelectrics based on hafnium oxide

High-k dielectrics

Neuromorphic devices

Oxide resistive memory

Transition metal dichalcogenides

Two-dimensional materials

11 citations

Chernikova Anna

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Zenkevich Andrei

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Oganov Artem

🥼 🤝

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Skolkovo Institute of Science and Technology

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Blügel Stefan

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Forschungszentrum Jülich

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Kruglov Ivan

PhD in Physics and Mathematics

57 publications, 2 449 citations, 9 reviews

h-index: 26

Dukhov Research Institute of Automatics

Moscow Institute of Physics and Technology

Research interests

Computer simulation

Condensed matter physics

Density functional theory (DFT)

Machine learning

1 citation

Propad Yana

🥼

5 publications, 38 citations

h-index: 3

Moscow Institute of Physics and Technology

Research interests

Crystallography

Density functional theory (DFT)

Machine learning

Materials Science

Superconductivity

1 citation

Yuan Yifan

🥼 🤝

PhD in Engineering, associate professor

19 publications, 137 citations, 3 reviews

h-index: 7

Nanjing University of Aeronautics and Astronautics

Research interests

Quantum materials

Spintronics

1 citation

Kuzmichev Dmitry

PhD in Physics and Mathematics

13 publications, 276 citations, 1 review

h-index: 8

Moscow Institute of Physics and Technology

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Park M. H. et al. Ferroelectricity and antiferroelectricity of doped thin HfO2-based films. // Advanced Materials. 2015. Vol. 27. No. 11. pp. 1811-1831.

GOST all authors (up to 50) Copy

Park M. H., Lee Y., Kim H., Kim Yu. J., Moon T., Kim K. D., Müller J., Kersch A., Schroeder U., Mikolajick T., Hwang C. M. Ferroelectricity and antiferroelectricity of doped thin HfO2-based films. // Advanced Materials. 2015. Vol. 27. No. 11. pp. 1811-1831.

RIS |

Cite this

RIS Copy

TY - JOUR

DO - 10.1002/adma.201404531

UR - https://doi.org/10.1002/adma.201404531

TI - Ferroelectricity and antiferroelectricity of doped thin HfO2-based films.

T2 - Advanced Materials

AU - Park, M H

AU - Lee, Younghwan

AU - Kim, Han-Joon

AU - Kim, Yu Jin

AU - Moon, Taehwan

AU - Kim, Keum Do

AU - Müller, Johannes

AU - Kersch, A.

AU - Schroeder, U.

AU - Mikolajick, Thomas

AU - Hwang, Cheol Mok

PY - 2015

DA - 2015/02/11

PB - Wiley

SP - 1811-1831

IS - 11

VL - 27

PMID - 25677113

SN - 0935-9648

SN - 1521-4095

ER -

BibTex |

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BibTex (up to 50 authors) Copy

@article{2015_Park,

author = {M H Park and Younghwan Lee and Han-Joon Kim and Yu Jin Kim and Taehwan Moon and Keum Do Kim and Johannes Müller and A. Kersch and U. Schroeder and Thomas Mikolajick and Cheol Mok Hwang},

title = {Ferroelectricity and antiferroelectricity of doped thin HfO2-based films.},

journal = {Advanced Materials},

year = {2015},

volume = {27},

publisher = {Wiley},

month = {feb},

url = {https://doi.org/10.1002/adma.201404531},

number = {11},

pages = {1811--1831},

doi = {10.1002/adma.201404531}

}

MLA

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MLA Copy

Park, M. H., et al. “Ferroelectricity and antiferroelectricity of doped thin HfO2-based films..” Advanced Materials, vol. 27, no. 11, Feb. 2015, pp. 1811-1831. https://doi.org/10.1002/adma.201404531.

Publisher

Wiley

Journal

Advanced Materials

scimago Q1

wos Q1

SJR

8.851

CiteScore

39.4

Impact factor

26.8

ISSN

09359648 (Print)

15214095 (Electronic)