Hydrogen-Induced Effect on Device Performance of a Pd/GaAs-Based Heterostructure Field-Effect Transistor

Abstract

On the basis of a GaAs-based heterostructure field-effect transistor with a catalytic Pd gate film, an interesting hydrogen sensor was fabricated and studied. A study of the hydrogen-induced dipole effect on device performance, including output resistance , Early voltage , and the drain saturation current operating regime, is reported. A significant change in the relative sensitivity ratio was observed in the cutoff region. In addition, a linear dependence between the logarithmic values of response time and hydrogen concentration is consistent with theoretical analysis. Experimentally, a high of in 9970 ppm was obtained in the cutoff region at . The width of the operating regime decreased from 115.3 to 108.2 mA/mm with an increase of the hydrogen concentration from air to 9970 ppm . From the experimental results, it is speculated that the polarization of a dipole layer reduces the depletion region, which results in a substantial change in the two-dimensional electron gas (2DEG) and the effective channel length and shape.