Regularities of the formation of binuclear homo- and heteroleptic complexes of d metals with 3,3′-bis(dipyrrolylmethenes) in DMF
25 May 2011-Russian Journal of Coordination Chemistry (SP MAIK Nauka/Interperiodica)-Vol. 37, Iss: 5, pp 333-342
TL;DR: In this paper, the reactions of seven symmetrically alkylated tetradentate ligands 3,3′-bis(dipyrrolylmethenes) (H2L) with d-metal acetates (M(AcO)2) were studied by spectrophotometry.
Abstract: The reactions of seven symmetrically alkylated tetradentate ligands 3,3′-bis(dipyrrolylmethenes) (H2L) with d-metal acetates (M(AcO)2) in DMF solutions at 298.15 K were studied by spectrophotometry. Helicands H2L were found to be structurally preorganized to form stable binuclear homoleptic two-helix helicates [M2L2] with Co(II), Ni(II), Cu(II), Zn(II), Cd(II), and Hg(II) acetates. The coordination of the ligands by the metal ions included consecutive stages of formation of the heteroleptic [M2L(AcO)2] and homoleptic [M2L2] complexes. The [M2L(AcO)2] complexes were spectrally revealed in solutions containing a ligand excess (cH2L / cM(AcO)2 > 1). An increase in the salt concentration shifted the system of equilibria to the homoligand product [M2L2]. The thermodynamic constants of the reactions increased in the series of complexing agents: Cu(II) < Cd(II) < Hg(II) < Ni(II) < Co(II) < Zn(II). An analysis of the data on the thermodynamic constants of [M2L2] helicate formation in solutions and the earlier obtained results of the IR and 1H NMR studies of the hydrobromic salts of the ligands (H2L · 2HBr) showed that the key regularities of the influence of the structural factors on the coordination properties of the ligands were in an increase in the stability of the [M2L2] complexes with an increase in the basicity of the ligands.
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TL;DR: In this article, a review highlights recent advances in new high sensitive and selective fluorescent chemosensors for metal ions based on the dipyrromethene platform with the advantages of bright color, significant fluorescence changes and simple structural functionalization.
65 citations
TL;DR: In this article, a review highlights recent advances devoted to new luminophores based on d -metal complexes of bis(dipyrrin)s of [M 2 L 2 ] and [Zn 2 l 2 ].
41 citations
TL;DR: A fluorescent chemosensor based on the 3,3′-bis(dipyrrin) bearing two chromophoric dipyrrin units was synthesized, which showed a strongly enhanced fluorescent intensity in the presence of Zn2+ ions and a high selectivity toward Zn 2+ ions over a wide range of tested metal ions in organic solvents.
Abstract: A fluorescent chemosensor based on the 3,3′-bis(dipyrrin) bearing two chromophoric dipyrrin units was synthesized, which showed a strongly enhanced fluorescent intensity in the presence of Zn2+ ions and a high selectivity toward Zn2+ ions over a wide range of tested metal ions in organic solvents.
22 citations
Cites background from "Regularities of the formation of bi..."
...It is known [22] that the ions of alkali and alkaline earth metals do not form stable complexes with 3,3′-bis(dipyrrin)s....
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TL;DR: In this paper, the off-on fluorescent chemosensor based on the bis(2,4,7,8,9-pentamethyldipyrrolylmethene-3-yl)methane for detection of Cd2+ and Hg2+ ions was obtained and its metal ion sensing properties were investigated.
19 citations
TL;DR: The effect of the attachment position of a methylene spacer in 2,2′-, 2,3′-, and 3, 3′-bis(dipyrromethene) N4-ligands (H2L) on physicochemical properties of dinuclear homoleptic helicates has been examined in this paper.
Abstract: The effect of the attachment position of a methylene spacer in 2,2′-, 2,3′-, and 3,3′-bis(dipyrromethene) N4-ligands (H2L) on physicochemical properties of their dinuclear homoleptic helicates [Zn2L2], such as specific features of their molecular structure, luminescence spectral characteristics, lability in acid solutions, and thermal stability in an argon atmosphere, has been examined It has been shown that the substitution of the biladiene-type helicand by its 2,3- and especially 3,3′-analogues leads to a considerable enhancement of the chromophoric properties, an increase (up to 30-fold) of the fluorescence quantum yield, and an increase in the stability of corresponding dinuclear helicates [Zn2L2]
18 citations
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536 citations
Book•
01 Apr 1989
TL;DR: In this article, the authors present a list of structural and structural aspects of linear Oligopyrroles, including the following: 5.1.1, 5.2.3.
Abstract: 1. Introduction.- 2. Nomenclature.- 3. Occurrence, Formation, and Importance.- 4. Historical Aspects.- 5. Structure and Stereochemistry.- 5.1. General Considerations.- 5.1.1. Definitions.- Constitution.- Tautomerism.- Configuration.- Conformation.- Association.- 5.1.2. Energetics, Interconversions, Interdependencies.- 5.1.3. Methods of Structural Analysis.- Crystalline Materials.- Amorphous Materials.- Solutions.- 5.1.4. Principal Considerations on Structural Aspects of Linear Oligopyrroles.- Bipyrroles.- Bipyrrolylidenes.- Dipyrrins (Pyrromethenes).- Dipyrrinones (Pyrromethenones).- 5,10-Dihydrodipyrrins (Dipyrrylmethanes).- Dihydrodipyrrinones (Dihydropyrromethenones).- Tetrahydrodipyrrinones (Tetrahydropyrromethenones).- Prodigiosenes.- Tripyrrinones.- 1,19-Dioxobilins.- Dihydrobilins: 1,19-Dioxobiladienes-ac.- Dihydrobilins: 1,19-Dioxobiladienes-ab.- Dihydrobilins:1,19-Dioxo-2,3-dihydrobilins.- Tetrahydrobilins: 1,19-Dioxobilenes-b.- Tetrahydrobilins: 1,19-Dioxo-2,3-dihydrobiladienes-ab.- Hexahydrobilins: 1,19-Dioxobilanes.- Hexahydrobilins: Bilanes.- Secocorrins.- 1,19-Dioxo-10-nor-bilins and 1,19-Dioxo-10-nor-biladienes-ac.- Pentapyrrins.- 5.2. Structural Aspects of Linear Dipyrroles.- 5.2.1. Bipyrroles, Bipyrrolylidenes, and Analoga.- 5.2.2. Dipyrrins (Pyrromethenes).- 5.2.3. Dipyrrinones (Pyrromethenones) and Analoga.- 5.2.4. 5,10-Dihydrodipyrrins (Dipyrrylmethanes).- 5.2.5. Dihydrodipyrrinones (Dihydropyrromethenones).- 5.2.6. Tetrahydrodipyrrinones (Tetrahydropyrromethenones).- 5.3. Structural Aspects of Linear Tripyrroles.- 5.3.1. Terpyrroles.- 5.3.2. Prodigiosenes.- 5.3.3. Tripyrrinones and Analoga.- 5.4. Structural Aspects of Linear Tetrapyrroles.- 5.4.1. 1,19-Dioxobilins and Bilins.- 5.4.2. Dihydrobilins: 1,19-Dioxo-2,3-dihydrobilins.- 5.4.3. Dihydrobilins: 1,19-Dioxobiladienes-ac.- 5.4.4. Dihydrobilins: 1,19-Dioxobiladienes-ab.- 5.4.5. Tetrahydrobilins: 1,19-Dioxo-2,3-dihydrobiladienes-ab.- 5.4.6. Tetrahydrobilins: 1,19-Dioxobilenes-b.- 5.4.7. Tetrahydrobilins: Secocorphins.- 5.4.8. Hexa- and Octahydrobilins.- 5.4.9. Secocorrins.- 5.4.10. 1,19-Dioxo-l0-nor- Bilins and Biladienes-ac.- 5.5. Structural Aspects of Linear Oligopyrroles Containing Five or More Rings.- 5.5.1. Pentapyrrins.- 5.5.2. Hexapyrrins and Higher Homologues.- 5.5.3. Polypyrrole.- 6. Synthesis.- 6.1. Principal Considerations.- 6.2. Synthesis of Linear Dipyrroles.- 6.2.1. Bipyrroles, Bipyrrolylidenes, and Analoga.- 6.2.2. Dipyrrins (Pyrromethenes) and Analoga.- 6.2.3. Dipyrrinones (Pyrromethenones) and Analoga.- 6.2.4. 5,10-Dihydrodipyrrins (Dipyrrylmethanes).- 6.2.5. Dihydrodipyrrinones (Dihydropyrromethenones).- 6.2.6. Tetrahydrodipyrrinones (Tetrahydropyrromethenones).- 6.2.7. Miscellaneous Dipyrroles.- 6.3. Synthesis of Linear Tripyrroles.- 6.4. Synthesis of Linear Tetrapyrroles.- 6.4.1. 1,19-Dioxobilins and Bilins.- 6.4.2. Dihydrobilins: 1,19-Dioxo-2,3-dihydrobilins.- 6.4.3. Dihydrobilins: 1,19-Dioxobiladienes-ac.- 6.4.4. Dihydrobilins: 1,19-Dioxobiladienes-ab.- 6.4.5. Tetrahydrobilins: 1,19-Dioxo-2,3-dihydrobiladienes-ab.- 6.4.6. Tetrahydrobilins: 1,19-Dioxobilenes-b.- 6.4.7. Tetrahydrobilins: Secocorphins.- 6.4.8. Hexahydrobilins and Octahydrobilins.- 6.4.9. Secocorrins.- 6.4.10. 1,19-Dioxo-l0-nor- Bilins and Biladienes-ac.- 6.5. Synthesis of Linear Pentapyrroles and Higher Homologues.- 6.6. Transformations of Functional Groups Attached to Linear Oligopyrroles.- 7. Selected Physical Properties.- 7.1. Crystallization, Melting, Solubility.- 7.2. Light Absorption.- 7.3. Chiroptical Properties.- 7.4. Light Emission.- 7.5. Vibrational Spectroscopy.- 7.6. Nuclear Magnetic Resonance.- 7.7. Mass Spectra.- 8. Reactions.- 8.1. Photochemistry.- 8.2. Protonation - Deprotonation.- 8.3. Coordination (Carrier Mediated Transport).- 8.4. Nucleophilic, Electrophilic, and Radical Reactivity of Linear Oligopyrroles.- 8.5. Substitution Reactions.- 8.6. Addition Reactions.- 8.7. Skeletal Transformations.- 8.8. Reduction - Oxidation.- 8.9. Linear Oligopyrroles as Catalysts.- References.- Author Index.
426 citations
"Regularities of the formation of bi..." refers background in this paper
...Neutral molecular complexes of 3,3' bis(dipyrrolylmethenes) also undergo no ionic dissociation in solutions [1, 6], and there are no liter ature data on the stability constants of these com plexes....
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...As in the related compounds (dipyrrolylmethenes, biladienes, and porphyrins), the N–H bond in the pyrrole rings of the 3,3' bis(dipyrrolylmethene) ligands does not undergo acidic dissociation due to the high strength, and in organic solvents the compounds exist in the molecular form [1, 6]....
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131 citations
TL;DR: These studies identify the crucial importance that the conformational preferences of the beta-beta' alkyl spacer group plays in the coordination algorithm of self-assembly to form dipyrromethene based complexes.
Abstract: Bis(dipyrromethene) ligands linked by an alkyl spacer between β and β‘ positions are shown to give helical dimers or monomers, dependent upon the length of the alkyl linker, upon complexation. Ligands consisting of methylene, ethylene, and propylene linkers −(CH2)n− (n = 1, 2, and 3) give helical dimers, while longer linking chains (n = 4, 5, or 6) give monomers or mixtures of dimers and monomers. X-ray crystal structures of the dimeric zinc complexes (n = 1, 2, and 3) reveal that the angles between dipyrromethene planes and the extent of helicity in the complexes differ as the length of the linker varies. The extent of helicity was assessed and found to be dependent upon the length and, specifically, the conformational preferences of the alkyl spacer unit. The presence of an ethylene linker gave complexes of greatest helicity. The use of a methylene spacer gave less helical structures upon complexation, while propylene spacers gave only slightly helical complexes. Our studies identify the crucial importa...
95 citations
Book•
01 Mar 1983
68 citations