Sarah J. Toal scite author profile

Colloidal suspensions of 3-aminopropylmethyl(tetraphenyl)silole nanoparticles can be used as selective chemosensors for carcinogenic chromium(VI) analyte. Methylhydrosilole is functionalized by hydrosilation of allylamine, and the colloid is prepared by the rapid addition of water to a THF solution of the silole. The method of detection is through electron-transfer quenching of the fluorescence of the silole colloid (lambda(em) = 485 nm at 360 nm excitation) by the analytes, with hundred parts per billion detection limits. Stern-Volmer plots are linear up to 10 ppm in the case of chromium, but exhibit saturation behavior near 5-10 ppm for arsenic. Dynamic light scattering experiments and AFM measurements show the particle sizes to be around 100 nm in diameter and dependent on solvent composition, with a particle size dispersity of +/-25%. The fluorescence lifetimes of the silole in solution and colloid are approximately 31 ps and approximately 4.3 ns, respectively, while the silole has a lifetime of 6 ns in the bulk solid. A minimum volume fraction of 80% water is necessary to precipitate the colloid from THF, and the luminescence continues to rise with higher water fractions. Colloids in a pH 7 phosphate-buffered suspension show both higher sensitivity and greater selectivity (100-fold) for CrO4(2-) detection than for other oxoanion interferents, NO3-, NO2-, SO4(2-), and ClO4-.

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Catalytic Hydrosilylation Routes to Divinylbenzene Bridged Silole and Silafluorene Polymers. Applications to Surface Imaging of Explosive Particulates

Sánchez

et al. 2008

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The syntheses, spectroscopic characterization, and fluorescence quenching efficiencies of 1,1silole-and 1,1-silafluorene-phenylenedivinylene polymers are reported. Model dimeric metallole compounds containing a phenylenedivinylene bridge have been synthesized to provide detailed structural and spectroscopic insight into conformational effects and electron delocalization. Poly((tetraphenyl)silole-phenylenedivinylene) and poly(silafluorene-phenylenedivinylene) both maintain a regioregular trans-vinylene Si-C backbone with σ*-π/π* conjugation. Various hydrosilylation catalysts were screened to evaluate their ability to produce high molecular weight polymers and to direct a strictly trans product. Molecular weights (M w ) for these polymers are in the range of 8400-9600. Fluorescence spectroscopy shows a significant bathochromic shift for the silafluorene polymer from solution to the solid state. A surface detection method for the analysis of solid particulates of TNT, DNT, PA, RDX, HMX, Tetryl, TNG, and PETN by fluorescence quenching was explored. The blue-emitting silafluorene polymer exhibited improved sensitivity for detecting explosive particle residues as compared to previously reported metallole polymers. Detection limits as low as 100 pg cm -2 for TNT are obtained. The Stern-Volmer equation quantitatively models the fluorescence quenching of these polymers by TNT, RDX, and PETN in thin solid-state films.

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Luminescent oligo(tetraphenyl)silole nanoparticles as chemical sensors for aqueous TNT

2005

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Visual Detection of Trace Nitroaromatic Explosive Residue Using Photoluminescent Metallole‐Containing Polymers

Toal

Sánchez

Dugan³

et al. 2006

Journal of Forensic Sciences

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The detection of trace explosives is important for forensic, military, and homeland security applications. Detection of widely used nitroaromatic explosives (trinitrotoluene [TNT], 2,4-dinitrotoluene [DNT], picric acid [PA]) was carried out using photoluminescent metallole-containing polymers. The method of detection is through the quenching of fluorescence of thin films of the polymer, prepared by spray coating organic solutions of the polymer, by the explosive analyte. Visual quenching of luminescence (lambda(em) approximately 400-510 nm) in the presence of the explosive is seen immediately upon illumination with near-UV light (lambda(ex)=360 nm). Detection limits were observed to be as low as 5 ng for TNT, 20 ng for DNT, and 5 ng for PA. In addition, experiments with normal production line explosives and their components show that this technology is also able to detect composition B, Pyrodex, and nitromethane. This method offers a convenient and sensitive method of detection of trace nitroaromatic explosive residue.

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Sarah J. Toal

Polymer sensors for nitroaromatic explosives detection

Luminescent Silole Nanoparticles as Chemoselective Sensors for Cr(VI)

Catalytic Hydrosilylation Routes to Divinylbenzene Bridged Silole and Silafluorene Polymers. Applications to Surface Imaging of Explosive Particulates

Luminescent oligo(tetraphenyl)silole nanoparticles as chemical sensors for aqueous TNT

Visual Detection of Trace Nitroaromatic Explosive Residue Using Photoluminescent Metallole‐Containing Polymers

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