A dense rutile TiO2 thin film was synthesized by the thermal oxidation of a sputtered titanium metal film in ambient air. The effects on optical properties of TiO2 films of the crystal structure and microstructural evolution at various oxidation temperatures were investigated. The Ti films transformed into single-phase rutile TiO2 at temperatures ⩾ 550 °C without going through an anatase-to-rutile transformation. Instead, an additional crystalline Ti2O phase was detected at 550 °C only. An increase in the oxidation temperatures ranging between 700 and 900 °C led to an increase in both the refractive index and absorption coefficient, but a decrease in the band gap energy (Eg). According to the coherent potential approximation model, the band gap evolution of the oxidized films was primarily attributed to the electronic disorder due to oxygen deficiency at a higher oxidation temperature rather than the presence of an amorphous component in the prepared films.
The enhancement of
upconversion luminescence (UCL) of rare earth doped upconversion nanoparticles
(UCNPs) in aqueous solution is particularly important and urgently
required for a broad range of biomedical applications. Herein, an
effective approach to achieve highly enhanced UCL from NaYF4:Yb3+,Tm3+ UCNPs in aqueous solution is presented.
We demonstrate that UCL of these UCNPs can be enhanced more than 104-fold by using a mesoporous silica low refractive index resonant
waveguide grating (low-n RWG) in contact with aqueous solution, which
makes it well-suited for biomedical applications. The structure parameters
of the low-n RWG are tuned via rigorous coupled-wave analysis simulation
to ensure strong local excitation field to form atop the TiO2 surface of the low-n RWG, where UCNPs are deposited. As the low-n
RWG is excited by a near-infrared laser at 976 nm to match its guided
mode resonance (GMR) condition, UCL emitted from UCNPs is greatly
enhanced thanks to the strong interaction between excitation local
field and UCNPs. UCL emission of UCNPs can be further enhanced about
two to four times when the UCL emission condition (wavelength and
angle) matches with the GMR condition. Furthermore, we show that the
presence of biotin molecules atop of the low-n RWG can be easily detected
through UCL emission generated from streptavidin-functionalized UCNPs
with the help of the streptavidin–biotin specific binding.
The results indicate that the low-n RWG has high potential for UCL
biosensing and bioimaging applications.
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