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

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

Synthesis of High-Aspect-Ratio CuO Nanowires for Conductometric Gas Sensing

AbstractCupric oxide (CuO) nanowires were synthesized by thermal oxidation of resistively heated copper wires in ambient air conditions. Aspect ratios up to 1000 have been achieved with this easy growth method that requires only standard laboratory equipment. The as-synthesized nanowires were subsequently transferred to silicon substrates and contacted by a structured metallization layer. These devices were used for conductometric gas sensing as nanowire conductivity is strongly dependent on the surrounding gas atmosphere. The sensitivity of a single CuO nanowire towards water vapour and hydrogen sulfide (H2S) was investigated regarding a possible application in hydrogen fuel cells