Thermal stability analysis of AlGaAs/GaAs heterojunction bipolar transistors with multiple emitter fingers

A numerical electro-thermal model was developed for AlGaAs/GaAs heterojunction bipolar transistors (HBT's) to describe the base current, current gain and output power dependence on junction temperature. The model is applied to microwave HBT devices with multi-emitter fingers. The calculated results of the common-emitter, current-voltage characteristics in the linear active region show a "current crush" effect due to inherent nonuniform junction temperature, current density and current gain distribution in the device. The formation of highly localized high temperature regions, i.e., hot spots, occur when the device is operating beyond the current-crush point. This thermally induced current instability imposes an upper limit on the power capability of HBT's. The dependence of this effect on various factors is discussed. These factors include the intrinsic parameters such as the base current ideality factor, the "apparent" valence band discontinuity, and the temperature coefficient of the emitter-base turn-on voltage, as well as the extrinsic factors such as the emitter contact specific resistance, the substrate thermal conductivity and the heat source layout. >

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