3,5-Dimethyl and 3,5-Di-<i>tert</i>-butylpyrazolato Complexes with Alkali Metals:  Monomeric, Dimeric, Cluster, and 1D Chain Structures

Cortés-Llamas, Sara-Angélica; Hernández‐Lamoneda, Ramón; Velázquez-Carmona, Miguel-Ángel; Muñoz‐Hernández, Miguel‐Ángel; Toscano, Rubén A.

doi:10.1021/ic051294y

Cited by 29 publications

(35 citation statements)

References 27 publications

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“…In the case of the pyrazoles and imidazoles substituted by alkaline and alkaline-earth elements, two different minima structures have been found, one interacting with the nitrogen atom and the second one above the ring interacting with its p-cloud, in agreement with recent theoretical and experimental reports [25,26]. The first minima is the global minima in the case of the pyrazoles and alkaline-earth derivatives of the imidazoles while in the case of the alkaline derivatives of the imidazoles the global minima is the second one.…”

Section: Geometriessupporting

confidence: 86%

Substitution effects in N-pyrazole and N-imidazole derivatives along the periodic table

et al. 2007

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A theoretical study of the monosubstitution effects of all the atoms of the second and third row of the periodic table on the pyrazole and imidazole rings has been carried out by means of B3LYP/6-31+G(d,p) DFT calculations. The geometric and electronic properties, calculated using the atoms in molecules methodology, electrostatic potential, and frontier orbitals have been analyzed. Some of the results have been rationalized based on the electronegativity of the substituents. In addition, the different parameters obtained have been compared with aromaticity indexes (HOMA and NICS). A comparison with the results obtained for the corresponding N-pyrrole derivatives has been carried out.

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Section: Geometriessupporting

confidence: 86%

Substitution effects in N-pyrazole and N-imidazole derivatives along the periodic table

et al. 2007

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“…X‐ray crystallography confirmed the formation of an Et 2 O‐solvated dimeric lithium pyrazolate complex (Figure 1 a), with two four‐coordinate lithium ions bridged by two pyrazolate ligands bound in an η 2 fashion to one lithium ion and η 1 to the other. Thus, 1 has the highly unusual (pyrazolate) coordination of μ‐η 2 :η 1 ,2g, 9 which is reminiscent of carboxylate10 and formamidinate11 chemistry.…”

Section: Resultsmentioning

confidence: 99%

“…These complexes illustrate the wide variety of coordination modes possible for pyrazolate ligands, including the appearance of three new binding modes, with 2 and 4 providing variations on the cubane structural theme. Since this work was completed, a number of related lithium and sodium pyrazolates have been reported 9. We also report the structures of oxo‐centered M 8 cages [( t Bu 2 pz) 6 Li 8 O] ( 5 ) and [( t Bu 2 pz) 6 Na 8 O] ( 6 ), obtained as by‐products.…”

Section: Introductionmentioning

confidence: 98%

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Alkali‐Metal Pyrazolate Complexes with Unusual Pyrazolate Coordination Modes and Pseudocubane Motifs

Beaini

Deacon

Erven

et al. 2007

Chemistry An Asian Journal

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The dimeric complex [Li(Ph2pz)(OEt2)]2 (1) and tetrameric cluster [Na(Ph2pz)(thf)]4 (2) were prepared by treatment of alkali-metal reagents (nBuLi and Na{N(SiMe3)2}, respectively) with 3,5-diphenylpyrazole (Ph2pzH) in Et2O (1) or THF (2). The polymer [Na(tBu2pz)]n (3) was obtained from reaction at elevated temperature in a sealed tube between Na metal and 3,5-di-tert-butylpyrazole (tBu2pzH). The complex [Na4(tBu2pz)2(thf)3(obds)]2 (4; obds = (OSiMe2)2O) was obtained as a minor product from prolonged treatment of tBu2pzH with elemental sodium in a silicone-greased flask. All four alkali-metal pyrazolato complexes were characterized by IR and 1H NMR spectroscopy and X-ray crystallography.The Li dimer 1 displays mu-eta(2):eta(1) lithium-pyrazolato binding, in which both lithium atoms are four-coordinate. Room- and variable-temperature NMR studies (1H, 13C, and 7Li) of 1 suggest similar behavior in solution, with peaks coalescing at low temperatures. Complexes 2 and 4 display distorted cubane structures. In 2, all the sodium atoms are five-coordinate, whereas 4 contains two sodium/pyrazolate/thf clusters (4:2:3 ratio) bridged by two obds(2-) units, as well as two four-coordinate and two five-coordinate sodium atoms. Compound 3 is composed of two independent chains with the unusual coordination modes mu3-eta(5):eta(2):eta(2), mu3-eta(5):eta(2):eta(1), and mu3-eta(4):eta(2):eta(1), with five-, six-, and seven-coordinate sodium atoms. Two oxo-centered M8 cage complexes [(tBu2pz)6Li8O] (5) and [(tBu2pz)6Na8O] (6) were obtained as by-products from attempted preparation of [Li(tBu2pz)] and [Na(tBu2pz)], respectively, and their structures were determined.

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“…In the solid state the pyrazolato unit in NaL displays an unusual μ 2 -η 2 :η 1 bridging mode, leaving one side arm completely uncoordinated. While such coordination is rarely observed with compartmental pyrazole ligands such as HL, [29] sodium cation complexes formed with simple 3,5-di-alkyl-substituted pyrazole units (alkyl = methyl, [53,54] phenyl, [55] or tertbutyl [53,[55][56][57][58] ) show a diverse range of binding motifs. For example, structural determination of the sodium cation complex [55] Indeed, the pyrazole ring has been referred to as the "most flexible ligand group in coordination chemistry" and displays no fewer than 20 different coordination modes.…”

Section: Sodium Cation Complexmentioning

confidence: 99%

Improved Synthesis and Detailed Characterization of a Hybrid Pyrazole‐TACN Dinucleating Ligand

Dalle

Dechert

Meyer

2015

Zeitschrift anorg allge chemie

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Abstract. An improved synthetic procedure is reported for the hybrid ligand HL, composed of two TACN macrocycles bridged by a central pyrazole moiety. Detailed NMR spectroscopic characterization showed that asymmetry in this dinucleating organic scaffold can be induced at room temperature through the use of anhydrous conditions, owing to pyrazole-NH prototropy. Thermally induced line broadening allowed for an estimation of the thermodynamic parameters for this proton exchange reaction, giving ΔH ‡ = 46.

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3,5-Dimethyl and 3,5-Di-tert-butylpyrazolato Complexes with Alkali Metals: Monomeric, Dimeric, Cluster, and 1D Chain Structures

Cited by 29 publications

References 27 publications

Substitution effects in N-pyrazole and N-imidazole derivatives along the periodic table

Substitution effects in N-pyrazole and N-imidazole derivatives along the periodic table

Alkali‐Metal Pyrazolate Complexes with Unusual Pyrazolate Coordination Modes and Pseudocubane Motifs

Improved Synthesis and Detailed Characterization of a Hybrid Pyrazole‐TACN Dinucleating Ligand

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