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Design Principle of Channel Material for Oxide-Semiconductor Field-Effect Transistor with High Thermal Stability and High On-current by Fluorine Doping

H. Kawai, Hiroshi Fujiwara, J. Kataoka, Nobuyoshi Saito, Tadashi Ueda, Toshiyuki Enda, Tohru Ishihara, Keiji Ikeda

202014 citationsDOI

Abstract

We propose material design guideline of oxide semiconductor field-effect transistor (OS-FET) based on first-principles calculation, and experimentally demonstrate excellent FET characteristics for the first time. Fluorine-doped In-Ga-Zn-O (IGZO) channel OS-FET exhibits both high thermal stability (>400°C) and high on-current at optimum F doping concentration which are required for co-integration with Si-CMOS as BEOL transistor. Our calculation revealed that high thermal stability comes from the release of overstress in IGZO by substitution of O by F. On the other hand, overdose of F decreases on-current by forming electron traps of metal-metal bonds. Considering these two different mechanisms behind, we successfully propose a breakthrough concept to improve thermal stability of OS-FET without degradation of on-current. Our results pave a new way for realizing high-performance BEOL transistors for 3D-LSI application.

Topics & Concepts

Materials scienceDopingTransistorThermal stabilityOptoelectronicsField-effect transistorCMOSSemiconductorOxideThermalDegradation (telecommunications)Current (fluid)Electronic engineeringNanotechnologyElectrical engineeringVoltageChemical engineeringEngineeringMetallurgyMeteorologyPhysicsZnO doping and propertiesSemiconductor materials and devicesThin-Film Transistor Technologies
Design Principle of Channel Material for Oxide-Semiconductor Field-Effect Transistor with High Thermal Stability and High On-current by Fluorine Doping | Litcius