Abstract:
The selective detection of gaseous benzene, toluene, ethylbenzene, and xylene
(BTEX) is challenging due to their similar molecular structures. In addition, BTEX
vapours are extremely hazardous and carcinogenic. Thus, in the current study, n-type
ZnO and p-type CuO nanostructures were synthesized utilizing various bases by a
simple hydrothermal method. Among the tested sensors, the ZnO-NaOH-based
sensor displayed a temperature dual-mode selectivity toward benzene with responses
(Ra/Rg) of 2.5 and 24 at 5 and 100 ppm, respectively at 75 C, and Ra/Rg 142 toward
xylene vapour at 100 ppm at an operating temperature of 150 C. While the CuO
based sensors showed a poor response, sensitivity, and selectivity towards tested
analytes. Moreover, the ZnO-NaOH based sensor revealed enormous sensitivity of
1.21 ppm-1 and a low limit of detection (LoD) of 0.018 ppm (i.e., 18 ppb) toward xylene.
The ultra-sensitivity, selectivity, and low LoD of ZnO-NaOH-based sensor toward
benzene and xylene are associated with the improved VO observed in the in-situ
photoluminescence and electron paramagnetic resonance studies, as well as the x
ray photoelectron spectroscopy analyses. The ZnO-NaOH-based sensor, which was
stored for roughly 18 months (547 days), demonstrated reliable repeatability and long
time operation stability for 22 hours of exposure to xylene. The superior sensitivity,
stability, and selectivity indicate openly that the strategy of using various bases is a
striking method for fabricating a temperature dual-mode selectivity for the detection of
benzene and xylene vapours.
Xylene is not just considered detrimental to the environment; it is also hazardous to
humans. Herein we report on xylene vapour detection using CuO-ZnO
heterostructures containing various concentrations (0.1-1.0 wt. %) of ZnO, prepared
via hydrothermal synthesis. X-ray diffraction, scanning, and transmission electron
microscopy, as well as x-ray photoelectron spectroscopy, validated the formation of
the CuO-ZnO heterostructure. Gas detection, sensitivity, selectivity and stability tests
of nine different gases, namely benzene, toluene, ethylbenzene, xylene, ethanol,
methane, SO2, NO2, and CO2 at various operational temperatures were subsequently
investigated. It was found that a CuO-ZnO heterostructure with 1.0 wt. % ZnO showed
excellent selectivity towards 100 ppm of xylene at 100 C. The sensor further
demonstrated an insignificant cross-sensitivity (Sxylene/Stoluene= 2.7) and (Sxylene/Sbenzene
= 8.5) towards toluene and benzene vapour. Additionally, the ultra-low limit of
detection of 9.5 ppb and sensitivity of 0.063 ppm-1 were observed towards xylene
vapour, which indicated that the CuO-ZnO (1.0 wt. %) heterostructure-based sensor
can produce sub-ppb-level xylene concentration. The sensor disclosed excellent long
term stability in dry air and 40% relative humidity.
Finally, at room temperature, the CuO-ZnO (0.5 wt. %) based sensor disclosed a
superior selectivity towards NO2. Additionally, concerning other gases, the sensors
showed poor responses at room temperature. While at higher temperatures, the
sensors showed better selectivity towards xylene. Thus, these findings showed that
while the sensors could detect xylene at high temperatures, nonetheless, the room
temperature sensitivity of the CuO-ZnO (0.5 wt. %) based sensor towards NO2
denoted that the sensor could be used for low power consumption. The superior gas
sensing characteristics could be ascribed to the creation of p-n heterojunction, the
robust chemical affinity, and the catalytic performance of p-type CuO on xylene and
NO2 gases.