posted on 2024-05-23, 09:03authored byZeyi Wu, Mengyao Su, Xiangyu Song, Denghua Li, Xinyuan Li, Jiajia Liu, Jiatao Zhang
Surface
termination and defects of metal oxide semiconductors are
crucial in the process of gas adsorption–desorption and signal
transduction, thereby determining their sensing performance. Herein,
a facile solvent-assisted surface engineering strategy was demonstrated
to synthesize anatase TiO2 nanosheets (TNS) for an ultraviolet
(UV) light-activated isopropanol (IPA) gas sensor. Surface-fluorinated
TiO2 nanosheets (F-TNS) were first synthesized by the hydrofluoric
acid-assisted hydrothermal method and followed by hydrothermally treating
in Na2S solutions with different concentrations. The effect
of the progressive removal of fluorides was discussed in detail based
on X-ray photoelectron spectroscopy (XPS), diffuse reflectance spectroscopy
(DRS), electrochemical impedance spectroscopy (EIS), and in situ Fourier
transform infrared (FTIR) spectroscopy analyses. Compared with F-TNS,
the chemiresistive sensor based on the TNS with a trace amount of
fluorine exhibited a 324% increase in the sensitivity to 50 ppm of
isopropanol at 50 °C under UV irradiation (λ = 365 nm,
30 mW/cm2), while it exhibited a 45% decrease in the recovery
time. The enhanced isopropanol sensing performance could be attributed
to the high surface area, rational surface terminations, oxygen vacancies,
and UV photoexcited charge carriers, which further modulate the surface
reaction and charge transfer. These findings offer a facile strategy
for the rational design of oxide-based sensing materials, which help
in understanding the function of surface terminations and defects
in gas sensing.