Backside Ferroelectric-Assisted Charge Trap Flash (BF-CTF) Device for a Wide Memory Window and Read Disturbance-Free Performance

Jaejoong Jeong; Yeeun Kim; Youngkeun Park; Jong Kyung Park; Byung Jin Cho

doi:10.1109/LED.2025.3603028

Backside Ferroelectric-Assisted Charge Trap Flash (BF-CTF) Device for a Wide Memory Window and Read Disturbance-Free Performance

Jaejoong Jeong, Yeeun Kim, Youngkeun Park, Jong Kyung Park, Byung Jin Cho

Dept. of Semiconductor Engineering

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

Abstract

A novel memory device structure, called backside ferroelectric-assisted charge trap flash (BF-CTF), has been proposed. The ferroelectric layer at the backside of the polysilicon channel can be polarized by the front gate voltage due to the speed difference between polarization and the inversion layer generation. The backside polarization can modulate the body potential and make additional threshold voltage (V_th) shift, providing additional memory window. The BF-CTF device exhibits significantly improved memory performance such as increased memory window, reduced program/erase time, and improved charge retention. More importantly, the BF-CTF device does not suffer from read disturbance problems originated from the minor loop of ferroelectric, as the ferroelectric polarization is decoupled from the read operation.

Original language	English
Pages (from-to)	2181-2184
Number of pages	4
Journal	IEEE Electron Device Letters
Volume	46
Issue number	11
DOIs	https://doi.org/10.1109/LED.2025.3603028
State	Published - 2025

Keywords

Ferroelectrics
charge trap flash (CTF)
disturbance
ferroelectric field-effect transistor (Fe-FET)
memory window

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10.1109/LED.2025.3603028

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title = "Backside Ferroelectric-Assisted Charge Trap Flash (BF-CTF) Device for a Wide Memory Window and Read Disturbance-Free Performance",

abstract = "A novel memory device structure, called backside ferroelectric-assisted charge trap flash (BF-CTF), has been proposed. The ferroelectric layer at the backside of the polysilicon channel can be polarized by the front gate voltage due to the speed difference between polarization and the inversion layer generation. The backside polarization can modulate the body potential and make additional threshold voltage (Vth) shift, providing additional memory window. The BF-CTF device exhibits significantly improved memory performance such as increased memory window, reduced program/erase time, and improved charge retention. More importantly, the BF-CTF device does not suffer from read disturbance problems originated from the minor loop of ferroelectric, as the ferroelectric polarization is decoupled from the read operation.",

keywords = "Ferroelectrics, charge trap flash (CTF), disturbance, ferroelectric field-effect transistor (Fe-FET), memory window",

author = "Jaejoong Jeong and Yeeun Kim and Youngkeun Park and Park, \{Jong Kyung\} and Cho, \{Byung Jin\}",

note = "Publisher Copyright: {\textcopyright} 1980-2012 IEEE.",

year = "2025",

doi = "10.1109/LED.2025.3603028",

language = "English",

volume = "46",

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journal = "IEEE Electron Device Letters",

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T1 - Backside Ferroelectric-Assisted Charge Trap Flash (BF-CTF) Device for a Wide Memory Window and Read Disturbance-Free Performance

AU - Jeong, Jaejoong

AU - Kim, Yeeun

AU - Park, Youngkeun

AU - Park, Jong Kyung

AU - Cho, Byung Jin

PY - 2025

Y1 - 2025

N2 - A novel memory device structure, called backside ferroelectric-assisted charge trap flash (BF-CTF), has been proposed. The ferroelectric layer at the backside of the polysilicon channel can be polarized by the front gate voltage due to the speed difference between polarization and the inversion layer generation. The backside polarization can modulate the body potential and make additional threshold voltage (Vth) shift, providing additional memory window. The BF-CTF device exhibits significantly improved memory performance such as increased memory window, reduced program/erase time, and improved charge retention. More importantly, the BF-CTF device does not suffer from read disturbance problems originated from the minor loop of ferroelectric, as the ferroelectric polarization is decoupled from the read operation.

AB - A novel memory device structure, called backside ferroelectric-assisted charge trap flash (BF-CTF), has been proposed. The ferroelectric layer at the backside of the polysilicon channel can be polarized by the front gate voltage due to the speed difference between polarization and the inversion layer generation. The backside polarization can modulate the body potential and make additional threshold voltage (Vth) shift, providing additional memory window. The BF-CTF device exhibits significantly improved memory performance such as increased memory window, reduced program/erase time, and improved charge retention. More importantly, the BF-CTF device does not suffer from read disturbance problems originated from the minor loop of ferroelectric, as the ferroelectric polarization is decoupled from the read operation.

KW - Ferroelectrics

KW - charge trap flash (CTF)

KW - disturbance

KW - ferroelectric field-effect transistor (Fe-FET)

KW - memory window

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DO - 10.1109/LED.2025.3603028

M3 - Article

AN - SCOPUS:105014354286

SN - 0741-3106

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SP - 2181

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JO - IEEE Electron Device Letters

JF - IEEE Electron Device Letters

IS - 11

ER -

Backside Ferroelectric-Assisted Charge Trap Flash (BF-CTF) Device for a Wide Memory Window and Read Disturbance-Free Performance

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Keywords

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