A pyrene-based fluorescent
chemosensor APSB [
N
-(pyrene-1-ylmethylene) anthracen-2-amine]
was designed and developed
by a simple condensation reaction between pyrene carboxaldehyde and
2-aminoanthracene. The APSB fluorescent sensor selectively binds Fe
3+
in the presence of other metal ions. Apart from this, APSB
shows high selectivity and sensitivity toward Fe
3+
ion
detection. The detection limit for APSB was 1.95 nM, and the binding
constant (
K
b
) was obtained as 8.20 ×
10
5
M
–1
in DMSO/water (95/5, v/v) medium.
The fluorescence quantum yields for APSB and APSB–Fe
3+
were calculated as 0.035 and 0.573, respectively. The function of
this fluorescent sensor APSB can be explained through the photo-induced
electron transfer mechanism which was further proved by density functional
theory studies. Finally, a live-cell image study of APSB in HeLa cells
was also carried out to investigate the cell permeability of APSB
and its efficiency for selective detection of Fe
3+
in living
cells.
Here, we described a cheap and effective chemosensor
(NHPyTSC)
that can distinguish Hg2+ and Zn2+ ions from
other metal ions and evaluated this phenomenon using several spectroscopy
techniques. With the addition of mercury and zinc ions, the proposed
chemosensor in particular showed noticeable changes in color and absorption
spectra. Additionally, by including EDTA in the NHPyTSC-Hg2+ and NHPyTSC-Zn2+ solutions, colorimetry readings can
be reversed. We developed a molecular-scale sequential information
processing circuit and presented the “writing–reading–erasing–reading”
and “multiwrite” behaviors in the form of binary logic
based on the great reversibility of this process. Moreover, by sequentially
adding Hg2+, Zn2+, and EDTA, NHPyTSC imitates
a molecular keypad lock and molecular logic gates. Density functional
theory (DFT) investigations provided more evidence of the Hg2+ and Zn2+ ions′ ability to attach to NHPyTSC. The
most interesting part of this work is that a study on the latent fingerprint
detection of the powder compound revealed that NHPyTSC exhibits good
adherence and finger ridge features without background stains. When
compared to black and white fingerprint powders, it is discovered
that the NHPyTSC powder produces results that are remarkably clear
on the majority of surfaces. This demonstrated their potential for
real-world use, particularly in the area of criminal investigations.
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