Shiming Bi scite author profile

Fluorescence-based detection is one of the most efficient and cost-effective methods for detecting hazardous, aqueous Hg 2+ . We designed a fluorescent porous organic polymer (TPA-POP-TSC), with a "fluorophore" backbone and a thiosemicarbazide "receptor" for Hg 2+ -targeted sensing. Nanometer-sized TPA-POP-TSC spheres (nanoPOP) were synthesized under mini-emulsion conditions and showed excellent solution processability and dispersity in aqueous solution. The nanoPOP sensor exhibits exceptional sensitivity (K sv = 1.01 × 10 6 M −1 ) and outstanding selectivity for Hg 2+ over other ions with rapid response and full recyclability. Furthermore, the nanoPOP material can be easily coated onto a paper substrate to afford naked eye-based Hg 2+detecting test strips that are convenient, inexpensive, fast, highly sensitive, and reusable. Our design takes advantage of the efficient and selective capture of Hg 2+ by thiosemicarbazides (binding energy = −29.84 kJ mol −1 ), which facilitates electron transfer from fluorophore to bound receptor, quenching the sensor's fluorescence.

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Porosity-induced emission: exploring color-controllable fluorescence of porous organic polymers and their chemical sensing applications

Liu

et al. 2015

J. Mater. Chem. C

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Most organic dyes dissipate their excitation energy in the aggregated state because of "aggregation caused quenching" effect, deteriorating their application in optoelectronic devices. To prevent "aggregation caused quenching" effect, we incorporate a dye-based fluorophore into a porous organic polymer skeleton because porosity would breed the spatial isolation of fluorophores to maintain its emission. Tuning the fraction of fluorophores in the skeleton of FL-SNW-DPPs would range the emission color covering from red to blue in both solid-state and suspension. More importantly, the combination of fluorescence and porosity of FL-SNW-DPPs would provide more space to transduce the molecular interaction between adsorbed analytes and fluorophores to the detectable changes in light emission, leading to the fluorescence-off or fluorescence-on detection of electron-deficient or electron-rich analytes.

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New diketopyrrolopyrrole (DPP) derivative as fluorescent probe for Zn2+

Zhang

Song

et al. 2013

Dyes and Pigments

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Shiming Bi

Duplex trapping and charge transfer with polysulfides by a diketopyrrolopyrrole-based organic framework for high-performance lithium–sulfur batteries

NanoPOP: Solution-Processable Fluorescent Porous Organic Polymer for Highly Sensitive, Selective, and Fast Naked Eye Detection of Mercury

Porosity-induced emission: exploring color-controllable fluorescence of porous organic polymers and their chemical sensing applications

New diketopyrrolopyrrole (DPP) derivative as fluorescent probe for Zn2+

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