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Band Engineering of Gate Interlayer for Low-voltage Operation and Enhanced Reliability in Gate-injection Type FeFETs

Authors
Kim, HoonKim, GiukChoi, HyojunJoh, HongraeKang, HyunjunPark, SanghyunSeo, KwangyouKim, KwangsooKim, WankiHa, DaewonAhn, JinhoJeon, Sanghun
Issue Date
Apr-2026
Publisher
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
Keywords
MINFIS FeFET; Gate IL engineering; Operating voltage; Reliability
Citation
IEEE ELECTRON DEVICE LETTERS, v.47, no.4, pp 728 - 731
Pages
4
Indexed
SCIE
SCOPUS
Journal Title
IEEE ELECTRON DEVICE LETTERS
Volume
47
Number
4
Start Page
728
End Page
731
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/213957
DOI
10.1109/LED.2026.3665112
ISSN
0741-3106
1558-0563
Abstract
A Metal-Gate Insulator (Gate IL)–Charge Trap Layer (CTL)–Ferroelectric (FE)–Channel Insulator (Channel IL)–Si (MINFIS) structure is proposed. The incorporation of the CTL enhances charge storage and broadens the memory window (MW), but it also results in a higher operating voltage compared with the conventional MIFIS structure. To address this limitation, we introduce an OTO (SiO2/TiO2/SiO2) Gate IL to replace the conventional ONO (SiO2/Si3N4/SiO2), and comparatively analyze the two structures. The OTO Gate IL reduces the operating voltage by incorporating a high-k TiO2 layer, which increases the electric field across the ferroelectric under the same applied bias and thereby accelerates the positive feedback between charge injection and ferroelectric switching. As a result, the OTO-MINFIS FeFET maintains a wide MW of 10.8 V while lowering the operating voltage to +18.5/–15.5 V, corresponding to a maximum reduction of 20.5% relative to the ONO-MINFIS device, when evaluated at the full achievable MW. Endurance tests up to 5 × 103 program/erase (PGM/ERS) cycles performed at an identical MW (~5 V) show ~5× smaller MW degradation. Post-cycling retention, measured up to 104 s, exhibits 32% lower ΔMW, confirming the superior reliability of the OTO stack. These findings demonstrate that Gate IL engineering with an OTO stack is an effective approach for achieving low-voltage and reliable ferroelectric memory devices.
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