posted on 2019-10-23, 08:29authored byDina N. Oosthuizen, David E. Motaung, André M. Strydom, Hendrik C. Swart
An approach to tailor the morphology
and sensing characteristics
of CuO nanoplatelets for selective detection of NO2 gas
is of great significance and an important step toward achieving the
challenge of improving air quality and in assuring the safety of mining
operations. As a result, in this study, we report on the NO2 room temperature gas-sensing characteristics of CuO nanoplatelets
and the underlying mechanism toward the gas-sensing performance by
altering the synthesis reaction base and time. High sensitivity of
∼40 ppm–1 to NO2 gas at room temperature
has been realized for gas sensors fabricated from CuO nanoplatelets,
using NaOH as base for reaction times of 45 and 60 min, respectively
at 75 °C. In both cases, the crystallite size, surface area,
and hole concentration of the respective materials influenced the
selectivity and sensitivity of the NO2 gas sensors. The
mechanism underpinning the superior NO2 gas sensing are
thoroughly discussed in terms of the crystallite size, hole concentration,
and surface area as active sites for gas adsorption.