2016

DOI: 10.1039/c5cc09752e

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A T-shaped triazatruxene probe for the naked-eye detection of HCl gas with high sensitivity and selectivity

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Abstract: A T-shaped Schiff-base triazatruxene derivative (TATNFF) was designed, synthesized, and explored as a sensitive probe to detect HCl gas by the naked eye. The remarkable color change of TATNFF with turn-on behavior in the presence of a trace amount of HCl gas was obviously observed by the naked eye, which opens up a new strategy to explore a novel set of smart responsive materials for sensing applications.

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Matthias Müller and Magnus R Buchner*1

Synthesis Of Ligand1

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Cited by 36 publications

(18 citation statements)

References 34 publications

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“…In situ reaction monitoring reveals an additional intense signal at 1.5 ppm which derives from HCl. [16] No further signals were observed, which leads to the conclusion that the benzoic acid is completely deprotonated. This finding is in agreement with the IR spectrum of compound 1 where no OÀHb and was observed.…”

Section: Matthias Müller and Magnus R Buchner*mentioning

confidence: 98%

Beryllium Complexes with Bio‐Relevant Functional Groups: Coordination Geometries and Binding Affinities

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2018

Angew Chem Int Ed

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The coordination mode around beryllium in proteins and the binding affinity towards the peptide are unknown because there have been no coordination compounds of beryllium with ligands bearing bio-relevant functional groups. We report the first comprehensive study on Be complexes with monodentate carboxylic acids, esters, aldehydes, and alcohols. Through solution and solid-state techniques we determined that the binding affinities of Be ions towards the functional groups are: carboxylate > alcohol > aldehyde > ester. Crystal structures of all the compounds have been determined including the unprecedented dodeca-nuclear macrocyclic ring structure of non-basic beryllium benzoate, which is the first example of those beryllium carboxylates. These findings enable the evaluation of potential beryllium binding sites inside proteins and is required to understand the mechanism of metal-triggered immune responses.

“…In situ reaction monitoring reveals an additional intense signal at 1.5 ppm which derives from HCl. [16] No further signals were observed, which leads to the conclusion that the benzoic acid is completely deprotonated. This finding is in agreement with the IR spectrum of compound 1 where no OÀHb and was observed.…”

Section: Matthias Müller and Magnus R Buchner*mentioning

confidence: 98%

Beryllium Complexes with Bio‐Relevant Functional Groups: Coordination Geometries and Binding Affinities

¹

,

²

2018

Angew Chem Int Ed

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The coordination mode around beryllium in proteins and the binding affinity towards the peptide are unknown because there have been no coordination compounds of beryllium with ligands bearing bio-relevant functional groups. We report the first comprehensive study on Be complexes with monodentate carboxylic acids, esters, aldehydes, and alcohols. Through solution and solid-state techniques we determined that the binding affinities of Be ions towards the functional groups are: carboxylate > alcohol > aldehyde > ester. Crystal structures of all the compounds have been determined including the unprecedented dodeca-nuclear macrocyclic ring structure of non-basic beryllium benzoate, which is the first example of those beryllium carboxylates. These findings enable the evaluation of potential beryllium binding sites inside proteins and is required to understand the mechanism of metal-triggered immune responses.

“…The heterocyclic organic ligand (L1) was synthesized by a single-step cyclization condensation reaction from oxindole in the presence of POCl 3 at reflux temperature [25]. The Cu (II) complex (Scheme 1) was synthesized using CuCl 2 •2H 2 O as the precursor and sodium diethyldithiocarbamate as a secondary ligand (L2).…”

Section: Synthesis Of Ligandmentioning

confidence: 99%

Electrochemical Detection of Chloride Ions by Copper (II) Complex with Mixed Ligand of Oxindole Derivative and Dithiocarbamates Moiety

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et al. 2019

Applied Sciences

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The present work describes the synthesis of a new copper (II) complex with bidentate ligands based on oxindole (indolin-2-one) derivatives, namely: 1H,1′H,1″H-[2,3′:2′,3″-terbenzo[b]pyrrol]-2″(3″H)-one (L1) and [sodium diethyldithiocarbamate (DTC)] (L2) as a second bidentate ligand. The ligand L1 was prepared by the cyclization reaction of oxindole (2-indolone) with phosphorus oxychloride. A mixed-ligand was synthesized using L1 and L2 ligands with copper (Cu (II)) via a simple reflux process. The synthesized mixed Cu (II) complex [C53H44CuN7O4S2 and [Cu(L1)2(L2)]2H2O] exhibited superior solubility in organic solvents like dichloromethane, chloroform, ethanol, methanol, DMF and DMSO. The optical characterizations revealed that the synthesized Cu (II) complex displayed a broad band (2Eg→2T2g) with the absorption at ~420 nm, suggesting a distorted octahedral geometry due to the strong Jahn-Teller distortion of the Cu2+ ion. The elemental analysis confirmed the existence of Cu, C, S, N, and other elements in the synthesized mixed Cu (II) complex. The physicochemical studies of the organic ligand and Cu(II) complex were investigated by TG analysis, NMR, FTIR, SEM, EDX, electronic spectra and cyclic voltammetry measurements. The detection of chloride ions with the prepared mixed Cu(II) complex was studied by cyclic voltammetry measurements at different scan rates.

“…However, I À ion was too large to insert into the space between C]N and the benzene ring of the TABD. 46,47 Thus, I À ion reacted with TABD uorogen by electrostatic interactions and offered more diffusion channels for the excitons to migrate, allowing them to be more quickly annihilated by the hydrogen iodide. 48 Next, when these lms were fumed with ammonia gas, halogen ion could react with NH 4 + due to the acid-base neutralization.…”

mentioning

confidence: 99%

Mechano-fluorochromic behavior of AEE polyurethane films and their high sensitivity to halogen acid gas

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(a) Polyurethanes with higher content of TABDAA2 presented better positive correlation between fluorescence and strain. (b) Sensing mechanism of STMPU-50 for detection of HCl.

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