Your search keyword '"Grogger, W."' showing total 3 results

1. Low-frequency noise characterization of single CuO nanowire gas sensor devices.

Author

Steinhauer, S., Köck, A., Gspan, C., Grogger, W., Vandamme, L. K. J., and Pogany, D.

Subjects

NANOWIRES, GAS detectors, NOISE, COPPER oxide, SPECTRAL energy distribution, HYDROXYL group

Abstract

Low-frequency noise properties of single CuO nanowire devices were investigated under gas sensor operation conditions in dry and humid synthetic air at 350 °C. A 1/f noise spectrum was found with the normalized power spectral density of current fluctuations typically a factor of 2 higher for humid compared to dry atmosphere. A core-shell nanowire model is proposed to treat the noise as parallel combination of gas-independent bulk and gas-dependent surface noise components. The observed increase in 1/f noise in the presence of water vapor is explained in terms of Hooge's mobility fluctuation model, where the increased surface noise component is attributed to carrier scattering at potential fluctuations due to hydroxyl groups at the nanowire surface. [ABSTRACT FROM AUTHOR]

Published

2015

2. Gas sensing properties of novel CuO nanowire devices.

Author

Steinhauer, S., Brunet, E., Maier, T., Mutinati, G.C., Köck, A., Freudenberg, O., Gspan, C., Grogger, W., Neuhold, A., and Resel, R.

Subjects

*NANOWIRE devices, *GAS detectors, *COPPER oxide, *METAL microstructure, *ELECTROPLATING, *THERMAL oxidation (Materials science), *CARBON monoxide, *TRANSMISSION electron microscopy

Abstract

Abstract: We report on novel gas sensing devices based on cupric oxide (CuO) nanowires which are synthesized on-chip by thermal oxidation of electroplated copper microstructures. This technique enables the direct integration of a multitude of CuO nanowires, which bridge the electrical contacts of a conductometric gas sensor. The CuO nanowire bridges exhibit a huge surface-to-volume ratio and are entirely surrounded by the gas atmosphere, which is a highly favorable gas sensor configuration. As a result, the CuO nanowire gas sensor devices are able to detect carbon monoxide (CO) down to a concentration of 10ppm and exhibit extraordinary sensitivity to hydrogen sulfide (H2S) where concentrations down to 10ppb have been detected, even in the presence of humidity. For characterization of the CuO nanowires, X-ray diffraction measurements, transmission electron microscopy and electron energy loss spectroscopy are employed. As no process temperatures higher than 400°C are required for the fabrication of the CuO nanowire devices, our approach can be employed in a CMOS backend process enabling the realization of a fully silicon integrated CuO nanowire gas sensing device. [Copyright &y& Elsevier]

Published

2013

3. Comparison of the gas sensing performance of SnO2 thin film and SnO2 nanowire sensors

Author

Brunet, E., Maier, T., Mutinati, G.C., Steinhauer, S., Köck, A., Gspan, C., and Grogger, W.

Subjects

*METALLIC films, *GAS detectors, *STANNIC oxide, *NANOWIRES, *COMPARATIVE studies, *TEMPERATURE effect, *HYDROGEN sulfide, *METHANE

Abstract

Abstract: In order to optimize the performance of gas sensor devices, nanocrystalline SnO2 thin film and single crystalline SnO2 nanowire sensors have been characterized for the target gases CO, CH4, H2, CO2, SO2 and H2S. At optimum operating temperature – varying from 250°C to 400°C – the SnO2 thin film sensor detects CO, CH4, CO2 and SO2 with responses in the range of 23–34%, H2 and H2S with responses above 80%. The SnO2 nanowire sensor shows responses in the range of 1–8% for CO, H2 and SO2, 29% for H2S, while CH4 and CO2 are not detected. Taking into account that the exposed surface area of the thin film sensor is 800 times larger than that of the single nanowire, we have correlated the number of CO gas molecules impinging the sensors’ surface with the number of electrons, which are actually detected as sensors’ response for the target gas CO. In case of the thin film sensor a single detected electron requires ∼2760 gas molecules impinging the sensor''s surface. For the nanowire sensor only ∼86 gas molecules are required for a single detected electron. The SnO2 nanowire sensor thus has a detection efficiency more than 30 times higher than the SnO2 thin film sensor, which we attribute to a lack of grain boundaries. From our measurements we conclude that single crystalline SnO2 nanowire sensors provide a higher sensitivity and an improved cross-sensitivity than their nanocrystalline counterpart. [Copyright &y& Elsevier]

Published

2012