Negative differential capacitance in ultrathin ferroelectric hafnia

Sanghyun Jo; Hyangsook Lee; Duk Hyun Choe; Jung Hwa Kim; Yun Seong Lee; Owoong Kwon; Seunggeol Nam; Yoonsang Park; Kihong Kim; Byeong Gyu Chae; Sangwook Kim; Seunghun Kang; Taehwan Moon; Hagyoul Bae; Jung Yeon Won; Dong Jin Yun; Myoungho Jeong; Hyun Hwi Lee; Yeonchoo Cho; Kwang Hee Lee; Hyun Jae Lee; Sangjun Lee; Kab Jin Nam; Dongjin Jung; Bong Jin Kuh; Daewon Ha; Yongsung Kim; Seongjun Park; Yunseok Kim; Eunha Lee; Jinseong Heo

doi:10.1038/s41928-023-00959-3

Negative differential capacitance in ultrathin ferroelectric hafnia

Sanghyun Jo^*
, Hyangsook Lee
, Duk Hyun Choe
, Jung Hwa Kim
, Yun Seong Lee
, Owoong Kwon
, Seunggeol Nam
, Yoonsang Park
, Kihong Kim
, Byeong Gyu Chae
, Sangwook Kim
, Seunghun Kang
, Taehwan Moon
, Hagyoul Bae
, Jung Yeon Won
, Dong Jin Yun
, Myoungho Jeong
, Hyun Hwi Lee
, Yeonchoo Cho
, Kwang Hee Lee

Hyun Jae Lee, Sangjun Lee, Kab Jin Nam, Dongjin Jung, Bong Jin Kuh, Daewon Ha, Yongsung Kim, Seongjun Park, Yunseok Kim, Eunha Lee^*, Jinseong Heo^*

^*Corresponding author for this work

Division of Electronic Engineering

Research output: Contribution to journal › Journal article › peer-review

52 Scopus citations

Abstract

Negative differential capacitance in ferroelectrics, which can be stabilized using a dielectric, could be used to overcome the limitations of capacitive coupling in electronic devices. However, the use of negative differential capacitance in scaled silicon-based structures—such as those used in advanced low-power logic devices—remains challenging. Here we report the electrical performance enhancement due to negative differential capacitance in metal–oxide–semiconductor capacitors based on ferroelectric zirconium-doped hafnia (Hf_0.5Zr_0.5O₂) with a thickness down to 1 nm. The devices exhibit superior performance to physically thinner control devices without the ferroelectric zirconium-doped hafnia. An S-shaped polarization–electric field relation verifies the negative differential capacitance effect. The effect is also achieved in field-effect transistors in which high-κ hafnia is replaced with the ferroelectric zirconium-doped hafnia, leading to an increase in on current and decrease in off current along with negative drain-induced barrier lowering. The negative differential capacitance exhibits endurance over more than 10¹⁵ cycles and can be tuned using doping that controls the interface charges.

Original language	English
Pages (from-to)	390-397
Number of pages	8
Journal	Nature Electronics
Volume	6
Issue number	5
DOIs	https://doi.org/10.1038/s41928-023-00959-3
State	Published - 2023.05

Quacquarelli Symonds(QS) Subject Topics

Materials Science
Engineering - Electrical & Electronic
Engineering - Petroleum
Physics & Astronomy

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10.1038/s41928-023-00959-3

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@article{b7c9088e22674bfc94a41d75e31bcaf7,

title = "Negative differential capacitance in ultrathin ferroelectric hafnia",

abstract = "Negative differential capacitance in ferroelectrics, which can be stabilized using a dielectric, could be used to overcome the limitations of capacitive coupling in electronic devices. However, the use of negative differential capacitance in scaled silicon-based structures—such as those used in advanced low-power logic devices—remains challenging. Here we report the electrical performance enhancement due to negative differential capacitance in metal–oxide–semiconductor capacitors based on ferroelectric zirconium-doped hafnia (Hf0.5Zr0.5O2) with a thickness down to 1 nm. The devices exhibit superior performance to physically thinner control devices without the ferroelectric zirconium-doped hafnia. An S-shaped polarization–electric field relation verifies the negative differential capacitance effect. The effect is also achieved in field-effect transistors in which high-κ hafnia is replaced with the ferroelectric zirconium-doped hafnia, leading to an increase in on current and decrease in off current along with negative drain-induced barrier lowering. The negative differential capacitance exhibits endurance over more than 1015 cycles and can be tuned using doping that controls the interface charges.",

author = "Sanghyun Jo and Hyangsook Lee and Choe, \{Duk Hyun\} and Kim, \{Jung Hwa\} and Lee, \{Yun Seong\} and Owoong Kwon and Seunggeol Nam and Yoonsang Park and Kihong Kim and Chae, \{Byeong Gyu\} and Sangwook Kim and Seunghun Kang and Taehwan Moon and Hagyoul Bae and Won, \{Jung Yeon\} and Yun, \{Dong Jin\} and Myoungho Jeong and Lee, \{Hyun Hwi\} and Yeonchoo Cho and Lee, \{Kwang Hee\} and Lee, \{Hyun Jae\} and Sangjun Lee and Nam, \{Kab Jin\} and Dongjin Jung and Kuh, \{Bong Jin\} and Daewon Ha and Yongsung Kim and Seongjun Park and Yunseok Kim and Eunha Lee and Jinseong Heo",

note = "Publisher Copyright: {\textcopyright} 2023, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2023",

month = may,

doi = "10.1038/s41928-023-00959-3",

language = "English",

volume = "6",

pages = "390--397",

journal = "Nature Electronics",

issn = "2520-1131",

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Jo, S, Lee, H, Choe, DH, Kim, JH, Lee, YS, Kwon, O, Nam, S, Park, Y, Kim, K, Chae, BG, Kim, S, Kang, S, Moon, T, Bae, H, Won, JY, Yun, DJ, Jeong, M, Lee, HH, Cho, Y, Lee, KH, Lee, HJ, Lee, S, Nam, KJ, Jung, D, Kuh, BJ, Ha, D, Kim, Y, Park, S, Kim, Y, Lee, E & Heo, J 2023, 'Negative differential capacitance in ultrathin ferroelectric hafnia', Nature Electronics, vol. 6, no. 5, pp. 390-397. https://doi.org/10.1038/s41928-023-00959-3

TY - JOUR

T1 - Negative differential capacitance in ultrathin ferroelectric hafnia

AU - Jo, Sanghyun

AU - Lee, Hyangsook

AU - Choe, Duk Hyun

AU - Kim, Jung Hwa

AU - Lee, Yun Seong

AU - Kwon, Owoong

AU - Nam, Seunggeol

AU - Park, Yoonsang

AU - Kim, Kihong

AU - Chae, Byeong Gyu

AU - Kim, Sangwook

AU - Kang, Seunghun

AU - Moon, Taehwan

AU - Bae, Hagyoul

AU - Won, Jung Yeon

AU - Yun, Dong Jin

AU - Jeong, Myoungho

AU - Lee, Hyun Hwi

AU - Cho, Yeonchoo

AU - Lee, Kwang Hee

AU - Lee, Hyun Jae

AU - Lee, Sangjun

AU - Nam, Kab Jin

AU - Jung, Dongjin

AU - Kuh, Bong Jin

AU - Ha, Daewon

AU - Kim, Yongsung

AU - Park, Seongjun

AU - Kim, Yunseok

AU - Lee, Eunha

AU - Heo, Jinseong

PY - 2023/5

Y1 - 2023/5

N2 - Negative differential capacitance in ferroelectrics, which can be stabilized using a dielectric, could be used to overcome the limitations of capacitive coupling in electronic devices. However, the use of negative differential capacitance in scaled silicon-based structures—such as those used in advanced low-power logic devices—remains challenging. Here we report the electrical performance enhancement due to negative differential capacitance in metal–oxide–semiconductor capacitors based on ferroelectric zirconium-doped hafnia (Hf0.5Zr0.5O2) with a thickness down to 1 nm. The devices exhibit superior performance to physically thinner control devices without the ferroelectric zirconium-doped hafnia. An S-shaped polarization–electric field relation verifies the negative differential capacitance effect. The effect is also achieved in field-effect transistors in which high-κ hafnia is replaced with the ferroelectric zirconium-doped hafnia, leading to an increase in on current and decrease in off current along with negative drain-induced barrier lowering. The negative differential capacitance exhibits endurance over more than 1015 cycles and can be tuned using doping that controls the interface charges.

AB - Negative differential capacitance in ferroelectrics, which can be stabilized using a dielectric, could be used to overcome the limitations of capacitive coupling in electronic devices. However, the use of negative differential capacitance in scaled silicon-based structures—such as those used in advanced low-power logic devices—remains challenging. Here we report the electrical performance enhancement due to negative differential capacitance in metal–oxide–semiconductor capacitors based on ferroelectric zirconium-doped hafnia (Hf0.5Zr0.5O2) with a thickness down to 1 nm. The devices exhibit superior performance to physically thinner control devices without the ferroelectric zirconium-doped hafnia. An S-shaped polarization–electric field relation verifies the negative differential capacitance effect. The effect is also achieved in field-effect transistors in which high-κ hafnia is replaced with the ferroelectric zirconium-doped hafnia, leading to an increase in on current and decrease in off current along with negative drain-induced barrier lowering. The negative differential capacitance exhibits endurance over more than 1015 cycles and can be tuned using doping that controls the interface charges.

UR - https://www.scopus.com/pages/publications/85157967532

U2 - 10.1038/s41928-023-00959-3

DO - 10.1038/s41928-023-00959-3

M3 - Journal article

AN - SCOPUS:85157967532

SN - 2520-1131

VL - 6

SP - 390

EP - 397

JO - Nature Electronics

JF - Nature Electronics

IS - 5

ER -

Negative differential capacitance in ultrathin ferroelectric hafnia

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