Bottom Contact 100 nm Channel‐Length α‐In<sub>2</sub>Se<sub>3</sub> In‐Plane Ferroelectric Memory

Shurong Miao; Ryosuke Nitta; Seiichiro Izawa; Yutaka Majima

doi:https://doi.org/10.1002/advs.202303032

Publication Information

Title

Japanese:	Bottom Contact 100 nm Channel‐Length α‐In₂Se₃ In‐Plane Ferroelectric Memory
English:	Bottom Contact 100 nm Channel‐Length α‐In₂Se₃ In‐Plane Ferroelectric Memory

Author

Japanese:	Shurong Miao, Ryosuke Nitta, 伊澤誠一郎, Yutaka Majima.
English:	Shurong Miao, Ryosuke Nitta, Seiichiro Izawa, Yutaka Majima.

Language

English

Journal/Book name

Japanese:	Advanced Science
English:	Advanced Science

Volume, Number, Page

Published date

Oct. 2023

Publisher

Japanese:
English:

Conference name

Japanese:
English:

Conference site

Japanese:
English:

Official URL

http://dx.doi.org/10.1002/advs.202303032

DOI

https://doi.org/10.1002/advs.202303032

Abstract

AbstractOwing to the emerging trend of non‐volatile memory and data‐centric computing, the demand for more functional materials and efficient device architecture at the nanoscale is becoming stringent. To date, 2D ferroelectrics are cultivated as channel materials in field‐effect transistors for their retentive and switchable dipoles and flexibility to be compacted into diverse structures and integration for intensive production. This study demonstrates the in‐plane (IP) ferroelectric memory effect of a 100 nm channel‐length 2D ferroelectric semiconductor α‐In2Se3 stamped onto nanogap electrodes on Si/SiO2 under a lateral electric field. As α‐In2Se3 forms the bottom contact of the nanogap electrodes, a large memory window of 13 V at drain voltage between ±6.5 V and the on/off ratio reaching 103 can be explained by controlled IP polarization. Furthermore, the memory effect is modulated by the bottom gate voltage of the Si substrate due to the intercorrelation between IP and out‐of‐plane (OOP) polarization. The non‐volatile memory characteristics including stable retention lasting 17 h, and endurance over 1200 cycles suggest a wide range of memory applications utilizing the lateral bottom contact structure.

Home

Search

Support

About T2R2

Related Links

Publication Information