16 μM in ACN). It was observed that Mizoribine cost after the Hg2+ addition, the colorless solution immediately becomes pink. It is interesting to notice that the color intensity of the solution is linearly dependent on the metal concentration. The color change in the chemosensor solution after Hg2+ addition is attributed to the chelator-metal binding. Thus, the colorimetric change produced during Hg2+ capture can be used as ‘naked-eye’ detection of this metallic contaminant in solution. Figure 3 Colorimetric changes in the NVP-BEZ235 molecular weight Rh-UTES derivative solutions. (a) Before Hg2+ addition and after Rh-UTES-Hg2+ complex formation at the following molar ratios: (b) 1:1, (c) 1:6, and (d) 1:10, respectively.
Rh-UTES concentration remained fixed at 1.16 μM in ACN solution. The photoluminescent properties of Rh-UTES derivative in solution were investigated toward the metal ion complexation. Figure 4a shows the excitation and emission spectra of Rh-UTES derivative with peaks centered at 513 and 583 nm, respectively. In the figure we can notice that the organic receptor exhibited a slight fluorescence emission. Upon the addition of increasing amount of Hg2+ ions (0.166 to 27.0 μM) to the solution of Rh-UTES receptor, a remarkable enhancement in the emission intensity was observed. This fluorescent enhancement is attributed to the formation of the Rh-UTES-Hg2+
complex. Thus, it is clear that the addition of Hg2+ ions ‘turns-on’ the fluorescence whereby the colorless weak fluorescent derivative changed to a colored highly fluorescent learn more complex, as was also shown in Figure 3. Additionally, we found that the Rh-UTES-Hg2+ complex presents a maximum emission at 11.9 μM Hg2+ concentration, after which a fluorescent quenching phenomenon was observed. The fluorescent intensity is reduced since some molecules of the complex act as a quencher (because the high concentration of the complex 5-Fluoracil chemical structure may induce a self-absorption process) which in turn decreases the number of molecules that can emit. Finally, after addition of 24.2 μM Hg2+ concentration, the fluorescent emission of complex
remains constant, which is attributed to the depletion of Rh-UTES derivative. Figure 4 Fluorescence response of Rh-UTES derivative in liquid phase at different metal concentration. Fluorescence response of Rh-UTES derivative in liquid phase (1 mM in ACN) upon addition of different concentrations of Hg2+ ions (0.166 to 27.0 μM). λ exc = 485 nm. The inset shows the fluorescence intensity of the Rh-UTES-Hg2+ complex as a function of [Hg2+]/[Rh-UTES] ratio. The fluorophore selectivity was also investigated by measuring the changes in the fluorescent emission produced by the addition of the following metal ions: Ag+, Hg2+, Ca2+, Pb2+, Li2+, Zn2+, Fe2+, Ni2+, K+, Cu2+, Na+, and Mn2+ to various solutions of Rh-UTES. The results are displayed in Figure 5; it is clear that the presence of these ions led to increases in the fluorescence intensity to varying degrees.