Papers by Author: Kun Wei Lin

Abstract: In this work, the comprehensive study of an interesting Pd/AlGaAs pseudomorphic high electron mobility transistor (pHEMT) based hydrogen sensor is implemented. The theoretical analysis and simulation are made by using a two-dimensional simulator Medici. In addition, a practical device is fabricated successfully. Based on the variations of the catalytic metal work function, the DC characteristics of experimental and simulated results are compared and studied.

Abstract: By combining the advantages of a catalytic palladium (Pd thin film) with a high-performance GaAs-based transistor, an interesting hydrogen sensor is fabricated and demonstrated. For the studied device, a 50 Å undoped GaAs cap layer is grown to prevent the Al0.24Ga0.76As Schottky layer from oxidizing and to suppress the Fermi level pinning effect. The sensing mechanism can be described as the dissociation of hydrogen molecules and the polarization of hydrogen atoms. The drain-source variation ΔIDS is caused by the polarization of a dipolar layer resulting in the modulation of the gate potential and carrier density level. Experimentally, a high hydrogen detection sensitivity SJ value of 275.8 mA/mm-ppm H2/air can be obtained under the 14ppm H2/air gas. Even under a very low hydrogen concentration (≤4.3 ppm H2/air) at 303K, the considerable current variation can be observed. Moreover, the fast hydrogen response is found. Therefore, the studied device reveals the promise for high-performance hydrogen sensor applications.