E. Zanoni, M. Meneghini, G. Meneghesso, F. Rampazzo, D. Marcon, V. G. Zhan, F. Chiocchetta, A. Graff, F. Altmann, M. Simon-Najasek, D. Poppitz
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引用次数: 3
Abstract
This paper reviews failure modes and mechanisms of 0.5 μm, 0.25 μm and 0.15 μm AlGaN/GaN HEMTs for microwave and millimeter-wave applications. Early devices adopting Ni/Pt/Au metallization were found to be affected by sidewall interdiffusion of Au and O, followed by electrochemical oxidation of AlGaN, a problem which was solved by adopting a new metallization and passivation scheme providing 0.25 μm devices capable of withstanding 24h at VDS = 60V, on-state, Tch = 375°C with no failure. 4000 h long-term thermal storage tests with no bias identified a non-monotonic behaviour of gate Schottky barrier height, causing a temporary increase of gate leakage current which presented no risk for device reliability. Beside contact-related degradation mechanisms, hot electron effects become increasingly more relevant during DC life tests (inducing a 10% increase of on-resistance), rf tests (creating or re-activating deep levels, which increase current-collapse and reduce rf output power and gain). RF tests are the harshest ones for hot-electron degradation, which represents the limiting factor for GaN HEMTs having LG ≤ 0.15 μm.
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