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Physics-Based α-IGZO TFTs Compact Modeling and Neural Network Application with 2T0C DRAM Cellopen access

Authors
Kim, HyoungsooPark, EunchanKwak, BeenKwon, DaewoongKim, Hyunwoo
Issue Date
Sep-2025
Publisher
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
Keywords
Electron traps; Integrated circuit modeling; Electrons; Semiconductor device modeling; Mathematical models; Accuracy; Logic gates; Electric potential; Fermi level; Tunneling; InGaZnOx (IGZO); compact model; neural network; oxide TFT; verilog; spice and simulation
Citation
IEEE ACCESS, v.13, pp 158751 - 158762
Pages
12
Indexed
SCIE
SCOPUS
Journal Title
IEEE ACCESS
Volume
13
Start Page
158751
End Page
158762
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/210447
DOI
10.1109/ACCESS.2025.3605345
ISSN
2169-3536
Abstract
Advanced amorphous oxide devices such as amorphous InGaZnO (α-IGZO) operate based on mechanisms that differ significantly from those of conventional Si-based devices, primarily due to structural differences. While both types of devices utilize field-effect mobility as the primary mode of charge transport, there is no consensus on the additional complexities involved in charge movement within α-IGZO devices, which arise from their unique material properties. The BSIM series model commonly used for silicon devices cannot fully explain the charge transport mechanism of α-IGZO devices. Unfortunately, physics-based compact models for α-IGZO, which reflect the intrinsic nature of charge transport involved in electrical conduction have not been completely proposed with a standard formula. This paper presents a compact model for α-IGZO TFTs that incorporates charge transport mechanisms such as percolation, Variable-Range Hopping (VRH), and Trap-Limited Conduction (TLC), along with a methodology for calculating surface potential using the Lambert W function. The model is implemented in Verilog-A for circuit-level simulation and provides high accuracy with fabricated devices measurement. The model’s performance is further evaluated using the MNIST dataset by comparing the classification accuracy across various shallow-layer neural network architectures, demonstrating the model’s potential in neuromorphic system applications.
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