Pour, G. Behzadi
Influence of oxide film surface morphology and thickness on the properties of gas sensitive nanostructure sensor - Vol.57(10), Oct - New Delhi CSIR 2019 - 743-749p.
In this study, the gas sensitive metal-oxide semiconductor (MOS) nanostructure sensors based on Ni thin film have been fabricated. The influences of SiO2film surface morphology and thickness on the response (R%) and electrical properties of the sensors have been investigated at 150 °C. The surface morphology of the SiO2film has been characterized by scanning electron microscopy (SEM) and atomic force microscopy (AFM). The C-V curves of the MOS nanostructure sensors in pure nitrogen and 2 % hydrogen have been reported as well. For the SiO2film thicknesses of 14, 65 and 74 nmthe measured flat-band voltages (VFB) are 0.7, 1.5 and 2 V, respectively. The responses of different sensors in 2% hydrogen for SiO2film thicknesses of 14 and 74 nm are 84% and 32%, respectively.The MOS nanostructure sensors exhibited good response to the hydrogen gas, with excellent sensitivity. The MOS nanostructure sensor based on Ni thin film and SiO2film thickness of 14 nm shows high response and sensitivity
Humanities and Applied Science
Influence of oxide film surface morphology and thickness on the properties of gas sensitive nanostructure sensor - Vol.57(10), Oct - New Delhi CSIR 2019 - 743-749p.
In this study, the gas sensitive metal-oxide semiconductor (MOS) nanostructure sensors based on Ni thin film have been fabricated. The influences of SiO2film surface morphology and thickness on the response (R%) and electrical properties of the sensors have been investigated at 150 °C. The surface morphology of the SiO2film has been characterized by scanning electron microscopy (SEM) and atomic force microscopy (AFM). The C-V curves of the MOS nanostructure sensors in pure nitrogen and 2 % hydrogen have been reported as well. For the SiO2film thicknesses of 14, 65 and 74 nmthe measured flat-band voltages (VFB) are 0.7, 1.5 and 2 V, respectively. The responses of different sensors in 2% hydrogen for SiO2film thicknesses of 14 and 74 nm are 84% and 32%, respectively.The MOS nanostructure sensors exhibited good response to the hydrogen gas, with excellent sensitivity. The MOS nanostructure sensor based on Ni thin film and SiO2film thickness of 14 nm shows high response and sensitivity
Humanities and Applied Science