Herein, a one-pot protocol to synthesize tetracyclic triazole−piperazine−quinazolinone-fused N-heterocyclic scaffolds is reported. In this strategy, a tandem approach of two highly efficient synthetic reactions, click and cross-dehydrogentive coupling reactions, with high atom economy were employed to obtain the target N-fused scaffolds. Being highly functional group tolerable, this method has broad substrate scope. Interestingly, some of these derivatives showed strong white solid-state fluorescence.
Silver nanoparticle
shows distinctive electrochemical properties,
and it has a wide range of applications in most areas of science and
technology. In the current work we reported the synthesis of biliverdin
protected silver nanosurface (Ag-BV) that could sense Fe(III) ion
via reduction despite of their unfavorable reduction potential in
aqueous medium. The addition of Fe(III) to the Ag-BV suspension resulted
an initial red shift in its surface plasmon resonance (SPR) band (420–450
nm) and a color change from straw yellow to deep brown due to the
agglomeration of the nanoparticles. Subsequently a redox reaction
caused the disappearance of the deep brown color and a significant
blue shift occurred in its SPR band (up to 410 nm). The analysis further
suggested that the aromatic π system of biliverdin (BV) on the
Ag-BV nanosurface could make an electron carrier bridge that favors
the transfer of an electron from atomic silver to an empty d orbital
of Fe(III) ion. The reduction of Fe(III) ion resulted in oxidation
of silver nanoparticles and loss of the nanostructure, which were
evidenced in transmission electron microscopy analysis. Further investigation
revealed that the partial charge on the iron center was ∼+1.16
in the Fe(II)–biliverdin complex compared to ∼+1.26
in the Fe(III)–biliverdin complex, suggesting a shift of electron
density to the metal ion center. Thus, the biliverdin coated silver
nanoparticle could be useful as a specific metal ion detector and
a redox modulator for an Fe(III)/Fe(II) aqueous system. This might
be the first report of its kind as the sensing mechanism involves
an exceptional redox type phenomenon instead of mere coagulation of
the nanoparticles in the presence of specific ions and produces a
different color as an indicator for the ion detection.
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