Paolo Magnone scite author profile

Abstract-In this paper, we investigate the quality of MOSFET gate stacks where high-k materials are implemented as gate dielectrics. We evaluate both drain-and gate-current noises in order to obtain information about the defect content of the gate stack. We analyze how the overall quality of the gate stack depends on the kind of high-k material, on the interfacial layer thickness, on the kind of gate electrode material, on the strain engineering, and on the substrate type. This comprehensive study allows us to understand which issues need to be addressed in order to achieve improved quality of the gate stack from a 1/f noise point of view.Index Terms-Drain noise, gate noise, high-k dielectric, MOSFET, 1/f noise.

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Impact of the interfacial layer on the low-frequency noise (1/f) behavior of MOSFETs with advanced gate stacks

Crupi

Srinivasan

Magnone

et al. 2006

IEEE Electron Device Lett.

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Investigation of the p-GaN Gate Breakdown in Forward-Biased GaN-Based Power HEMTs

Tallarico

Stoffels

Magnone

et al. 2017

IEEE Electron Device Lett.

130

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PBTI in GaN-HEMTs With p-Type Gate: Role of the Aluminum Content on $\Delta V_{\mathrm {TH}}$ and Underlying Degradation Mechanisms

Tallarico

Stoffels

Posthuma

et al. 2018

IEEE Trans. Electron Devices

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Power-Based Droop Control in DC Microgrids Enabling Seamless Disconnection From Upstream Grids

Liu

Caldognetto

Mattavelli

et al. 2019

IEEE Trans. Power Electron.

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This paper proposes a local power-based droop controller for distributed energy resource converters in dc microgrids that are connected to upstream grids by grid-interface converters. During normal operation, the grid-interface converter imposes the microgrid bus voltage and the proposed controller allows power flow regulation at distributed energy resource converters output. On the other hand, during abnormal operation of the grid-interface converter (e.g., due to faults in the upstream grid), the proposed controller allows bus voltage regulation by droop control. Notably, the controller can autonomously convert from power flow control to droop control, without any need of bus voltage variations detection schemes or communication with other microgrid components, which enables seamless transitions between these two modes of operation. Considering distributed energy resource converters employing the power-based droop control, the operation modes of a single converter and of the whole microgrid are defined and investigated herein. The controller design is also introduced. Furthermore, the power sharing performance of this control approach is analyzed and compared with that of classical droop control. The experimental results from a laboratory-scale dc microgrid prototype are reported to show the final performances of the proposed power-based droop control.

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Paolo Magnone

$1/f$ Noise in Drain and Gate Current of MOSFETs With High-$k$ Gate Stacks

Impact of the interfacial layer on the low-frequency noise (1/f) behavior of MOSFETs with advanced gate stacks

Investigation of the p-GaN Gate Breakdown in Forward-Biased GaN-Based Power HEMTs

PBTI in GaN-HEMTs With p-Type Gate: Role of the Aluminum Content on $\Delta V_{\mathrm {TH}}$ and Underlying Degradation Mechanisms

Power-Based Droop Control in DC Microgrids Enabling Seamless Disconnection From Upstream Grids

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