In a previous paper we showed how simple drift-diffusion simulations backed up the hypothesis of electron trapping at the device surface between gate and drain as a mechanism able to consistently explain all of the experimentally observed degradation modes following a high-field (hot carrier) stress. This paper expands on such previous findings by showing: (i) simulation results of HFETs with different recess geometries, and their implications on breakdown voltage and reliability; (ii) a detailed experimental and numerical investigation of surface trapping effects such as gate lag, transconductance frequency dispersion, and drain current kink, and their relationship with device degradation.
Experimental/numerical investigation of the physical mechanisms behind high-field degradation of power HFETs and their implications on device design / R., Menozzi; G., Sozzi; Verzellesi, Giovanni; Borgarino, Mattia; C., Lanzieri; Canali, Claudio. - STAMPA. - (2001), pp. 89-95. (Intervento presentato al convegno GaAs Reliability Workshop tenutosi a Baltimore (Maryland, USA) nel Oct. 2001).
Experimental/numerical investigation of the physical mechanisms behind high-field degradation of power HFETs and their implications on device design
VERZELLESI, Giovanni;BORGARINO, Mattia;CANALI, Claudio
2001
Abstract
In a previous paper we showed how simple drift-diffusion simulations backed up the hypothesis of electron trapping at the device surface between gate and drain as a mechanism able to consistently explain all of the experimentally observed degradation modes following a high-field (hot carrier) stress. This paper expands on such previous findings by showing: (i) simulation results of HFETs with different recess geometries, and their implications on breakdown voltage and reliability; (ii) a detailed experimental and numerical investigation of surface trapping effects such as gate lag, transconductance frequency dispersion, and drain current kink, and their relationship with device degradation.
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