Hf-Based and Zr-Based Charge Trapping Layer Engineering for E-Mode GaN MIS-HEMT Using Ferroelectric Charge Trap Gate Stack

Wu, Jui-Sheng; Lee, Chih-Chieh; Wu, Chia-Hsun; Huang, Chengjun; Liang, Yan-Kui; Weng, You-Chen; Chang, Edward Yi

doi:10.1109/jeds.2022.3188463

Cited by 8 publications

References 24 publications

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Recent Progress of E‐mode Gallium Nitride Metal–Insulator–Semiconductor ‐High Electron Mobility Transistors with Hybrid Ferroelectric Charge Trap Gate (FEG‐HEMT) for Power Switching Applications

Weng

Yang

et al. 2023

Physica Status Solidi (a)

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Aluminum gallium nitride/gallium nitride (AlGaN/GaN) heterostructure devices have proven to be highly effective for high‐frequency power amplifiers and power switching applications with improved performance compared to those made with traditional silicon technology and other advanced semiconductor technologies. The development of enhancement‐mode (E‐mode) AlGaN/GaN high electron mobility transistors (HEMTs) and metal–insulator–semiconductor HEMTs (MIS‐HEMTs) has been a focus in recent years due to their potential applications. Arising from the concept of a flash‐memory‐like hybrid ferroelectric charge storage structure, the high‐performance hybrid ferroelectric charge storage gate (FEG) GaN HEMT has gradually gained a great deal of attention due to the concept being a useful and versatile tool to realize E‐mode operations. This article attempts to review the latest progresses in this technology, including alternative improvements and device characteristics. Future challenges for the E‐mode FEG‐HEMT are also discussed.

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Recent Progress of E‐mode Gallium Nitride Metal–Insulator–Semiconductor ‐High Electron Mobility Transistors with Hybrid Ferroelectric Charge Trap Gate (FEG‐HEMT) for Power Switching Applications

Weng

Yang

et al. 2023

Physica Status Solidi (a)

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Performance characterization of Ferroelectric GaN HEMT based biosensor

Topno,

Hemaja,

D.K.Panda

et al. 2024

Microsyst Technol

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Charge trapping layer enabled high-performance E-mode GaN HEMTs and monolithic integration GaN inverters

Jiang,

Du,

Wen

et al. 2024

Applied Physics Letters

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In this work, high threshold voltage and breakdown voltage E-mode GaN HEMTs using an Al:HfOx-based charge trapping layer (CTL) are presented. The developed GaN HEMTs exhibit a wide threshold modulation range of ΔVTH ∼ 17.8 V, which enables the achievement of enhancement-mode (E-mode) operation after initialization process owing to the high charge storage capacity of the Al:HfOx layer. The E-mode GaN HEMTs exhibit a high positive VTH of 8.4 V, a high IDS,max of 466 mA/mm, a low RON of 10.49 Ω mm, and a high on/off ratio of ∼109. Moreover, the off-state breakdown voltage reaches up to 1100 V, which is primarily attributed to in situ O3 pretreatment effectively suppressing and blocking leakage current. Furthermore, thanks to the VTH of GaN HEMTs being tunable by initialization voltage using the proposed CTL scheme, we prove that the direct-coupled FET logic-integrated GaN inverters can operate under a variety of conditions (β = 10–40 and VDD = 3–15 V) with commendable output swing and noise margins. These results present a promising approach toward realizing the monolithic integration of GaN devices for power IC applications.

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Hf-Based and Zr-Based Charge Trapping Layer Engineering for E-Mode GaN MIS-HEMT Using Ferroelectric Charge Trap Gate Stack

Cited by 8 publications

References 24 publications

Recent Progress of E‐mode Gallium Nitride Metal–Insulator–Semiconductor ‐High Electron Mobility Transistors with Hybrid Ferroelectric Charge Trap Gate (FEG‐HEMT) for Power Switching Applications

Recent Progress of E‐mode Gallium Nitride Metal–Insulator–Semiconductor ‐High Electron Mobility Transistors with Hybrid Ferroelectric Charge Trap Gate (FEG‐HEMT) for Power Switching Applications

Performance characterization of Ferroelectric GaN HEMT based biosensor

Charge trapping layer enabled high-performance E-mode GaN HEMTs and monolithic integration GaN inverters

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