Detection of Trace-Level Nitroaromatic Explosives by 1-Pyreneiodide-Ligated Luminescent Gold Nanostructures and Their Forensic Applications

Abstract: By attaching the1-pyreneiodide ancillary ligand to the surface of polyvinylpyrrolidone-stabilized gold (Au:PVP) cluster or the cetyltrimethyl ammonium bromide-stabilized gold (Au:CTAB) nanorod, a new class of luminescent mixed ligand-stabilized gold nanostructures is synthesized. This postsynthetic surface modification method followed by us is a comparatively easier and hassle-free technique to acquire surface-active luminescent “functional nanomaterials”. Careful analyses of transmission electron microscopy … Show more

“…To understand the sensing mechanism we have measured the hydrodynamic diameter (D h ) and excited state life times (τ) of the both clusters during gradual addition of some selected metal salts. In general the luminescence quenching phenomenon occurs through photo-induced electron transfer (PET) process via static or dynamic interaction between probe and the analyte [40][41][42][43][44][45][46][47][48]. However, the turn-on sensing is uncommon and the underlying mechanism may be very distinct for different probes [49][50][51].…”

“…Trace level detection of various analytes including metal ions, explosives, speci c biomolecules, toxic molecules and food contaminants by luminescent noble metal clusters is a promising approach [38][39][40][41][42][43].…”

Synthesis of Orange-Red Emissive Au-SG and AuAg-SG Nanoclusters and Their Turn-OFF vs. Turn-ON Metal Ion Sensing

“…To understand the sensing mechanism we have measured the hydrodynamic diameter (D h ) and excited state life times (τ) of the both clusters during gradual addition of some selected metal salts. In general the luminescence quenching phenomenon occurs through photo-induced electron transfer (PET) process via static or dynamic interaction between probe and the analyte [40][41][42][43][44][45][46][47][48]. However, the turn-on sensing is uncommon and the underlying mechanism may be very distinct for different probes [49][50][51].…”

“…Trace level detection of various analytes including metal ions, explosives, speci c biomolecules, toxic molecules and food contaminants by luminescent noble metal clusters is a promising approach [38][39][40][41][42][43].…”

Synthesis of Orange-Red Emissive Au-SG and AuAg-SG Nanoclusters and Their Turn-OFF vs. Turn-ON Metal Ion Sensing

“…The calorimetric and fluorescence-based explosive sensing is cost-effective, easy to use with fast response time, and hence ideal for on-the-spot testing of analytes. Various light emissive materials such as organic small molecules and polymers, , metal–organic frameworks, metal nanoclusters, − nanoassemblies, ,, and semiconductor nanoparticles (QDs) , have been synthesized and demonstrated as fluorescence sensors for explosive detection. Considering the high emission quantum yield, tunable band gap energy in the UV–vis region, and availability of hustle-free surface functionalization strategies, the use of QD-based fluorescence sensors is gaining more importance. , At the same time, to avoid toxic materials (e.g., Cd, Pb), heavy metal-free QDs for various sensing and optoelectronic applications have been a research priority in recent times. − Transition metal dichalcogenide-based QDs (MoX 2 , WX 2 , where X = S/Se) are very promising materials with size- and dimension-specific optical, photoluminescence, and electronic properties, ,− especially MoS 2 /Se 2 QDs are found to have inherent strong emission properties, high chemical stability, low toxicity, and easy surface functionalization procedures. , In the bulk phase of MoS 2 , two sulfur (S) atoms in two hexagonal planes are separated by an atomic plane of a molybdenum atom with excellent chemical and thermal stability.…”

Photoluminescent MoS₂ and MoSe₂ Quantum Dots for the Detection of Nitro-Organic Explosives

Nanomaterial-Based Sensors for the Detection of Explosives