Raised breakdown voltage in a high‐voltage recessed LDD‐SOI by submerged SI3N4

A new structure of metal‐oxide‐semiconductor field‐effect transistors (MOSFETs) with lateral double‐diffused MOSFET was introduced based on the silicon‐on‐insulator lightly doped‐drain metal‐oxide‐semiconductor field‐effect‐transistor (SOI‐LDD MOSFET) technology, called recessed silicon nitride late...

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Veröffentlicht in:	International journal of numerical modelling 2023-03, Vol.36 (2), p.n/a
Hauptverfasser:	Daneshpajooh, Reza, Anvarifard, Mohammad K.
Format:	Artikel
Sprache:	eng
Schlagworte:	Breakdown breakdown voltage buried oxide Buried structures Electric fields Electric potential lateral‐double diffused MOSFET MOSFETs Semiconductor devices SI3N4 Silicon nitride SOI (semiconductors) Transistors Voltage
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container_title	International journal of numerical modelling
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creator	Daneshpajooh, Reza Anvarifard, Mohammad K.
description	A new structure of metal‐oxide‐semiconductor field‐effect transistors (MOSFETs) with lateral double‐diffused MOSFET was introduced based on the silicon‐on‐insulator lightly doped‐drain metal‐oxide‐semiconductor field‐effect‐transistor (SOI‐LDD MOSFET) technology, called recessed silicon nitride lateral‐double diffused silicon‐on‐insulator (RS‐LDD SOI). In the proposed structure, a recession was created on the buried oxide layer and filled with a silicon nitride (SI3N4) layer. Silicon nitride makes the electric field distribution more uniform by modulating the electric field in the drift zone, thereby increasing the breakdown voltage of the proposed structure. The simulation results performed with ATLAS software demonstrated the performance improvement of the proposed structure. Increasing the breakdown voltage by 31% compared to the conventional structure was one of the most important achievements of this work. Also, design considerations were made on the submerged part in the buried oxide, which can be an excellent guide to achieving the optimal performance of the proposed structure.
doi_str_mv	10.1002/jnm.3044
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In the proposed structure, a recession was created on the buried oxide layer and filled with a silicon nitride (SI3N4) layer. Silicon nitride makes the electric field distribution more uniform by modulating the electric field in the drift zone, thereby increasing the breakdown voltage of the proposed structure. The simulation results performed with ATLAS software demonstrated the performance improvement of the proposed structure. Increasing the breakdown voltage by 31% compared to the conventional structure was one of the most important achievements of this work. 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subjects	Breakdown breakdown voltage buried oxide Buried structures Electric fields Electric potential lateral‐double diffused MOSFET MOSFETs Semiconductor devices SI3N4 Silicon nitride SOI (semiconductors) Transistors Voltage
title	Raised breakdown voltage in a high‐voltage recessed LDD‐SOI by submerged SI3N4
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