Metal sulfide Zn1–xCdxS nanowires (NWs)
covering the entire compositional
range prepared by one step solvothermal method were used to fabricate
gas sensors. This is the first time for ternary metal sulfide nanostructures
to be used in the field of gas sensing. Surprisingly, the sensors
based on Zn1–xCdxS nanowires were found to exhibit enhanced response to ethanol
compared to those of binary CdS and ZnS NWs. Especially for the sensor
based on the Zn1–xCdxS (x = 0.4) NWs, a large sensor response (s = 12.8) and a quick rise time (2 s) and recovery time
(1 s) were observed at 206 °C toward 20 ppm ethanol, showing
preferred selectivity. A dynamic equilibrium mechanism of oxygen molecules
absorption process and carrier intensity change in the NWs was used
to explain the higher response of Zn1–xCdxS. The reason for the much quicker
response and recovery speed of the Zn1–xCdxS NWs than those of the binary
ZnS NWs was also discussed. These results demonstrated that the growth
of metal sulfide Zn1–xCdxS nanostructures can be utilized to develop gas sensors
with high performance.