Trinuclear Gold–Carborane Cluster as a Host Structure

Aullón, Gabriel; Laguna, Antonio; Filippov, Oleg A.; Oliva‐Enrich, Josep M.

doi:10.1002/ejic.201801094

Cited by 8 publications

(10 citation statements)

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“…The parent compound (closo-B 10 H 12 C 2 ) has three different isomers depending on the relative disposition of the compound (closo-B10H12C2) has three different isomers depending on the relative disposition of the carbon atoms: ortho (closo-1,2-dicarbadodecarborane), meta (closo-1,7-dicarbadodecarborane) and para (closo-1,12-dicarbadodecarborane) (Scheme 1). Theoretical studies of the interaction of carboranes with biomolecules by means of dihydrogen bonds [50], the hydrogen bond with π-systems [51,52], halogen bonds [53,54], interaction with gold derivatives [55,56] and as superacids [57] In this article, we studied the complexes between a Lewis base, hydrogen cyanide (NCH), used as a hydrogen bond (HB) and halogen bond (XB) acceptor probe and 1-halo-closo-carboranes (Scheme 2) acting as hydrogen-and halogen-bond donors. The parent compounds X = H have also been considered.…”

Section: Introductionmentioning

confidence: 99%

Hydrogen vs. Halogen Bonds in 1-Halo-Closo-Carboranes

2020

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A theoretical study of the hydrogen bond (HB) and halogen bond (XB) complexes between 1-halo-closo-carboranes and hydrogen cyanide (NCH) as HB and XB probe has been carried out at the MP2 computational level. The energy results show that the HB complexes are more stable than the XBs for the same system, with the exception of the isoenergetic iodine derivatives. The analysis of the electron density with the quantum theory of atoms in molecules (QTAIM) shows the presence of a unique intermolecular bond critical point with the typical features of weak noncovalent interactions (small values of the electron density and positive Laplacian and total energy density). The natural energy decomposition analysis (NEDA) of the complexes shows that the HB and XB complexes are dominated by the charge-transfer and polarization terms, respectively. The work has been complemented with a search in the CSD database of analogous complexes and the comparison of the results, with those of the 1-halobenzene:NCH complexes showing smaller binding energies and larger intermolecular distances as compared to the 1-halo-closo-carboranes:NCH complexes.

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Section: Introductionmentioning

confidence: 99%

Hydrogen vs. Halogen Bonds in 1-Halo-Closo-Carboranes

2020

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“…[23] 1,2-Dicarboranyl ligands and the potentially chelating 2,2'-bis(dicarboranyl) dianion are more electron-withdrawingt han aryl ligands. [24] However,i nc ontrast to the large number of dicarboranyl derivatives of Au I , [25][26][27][28][29][30][31] to the best of our knowledge there are no reports of dicarboranyl complexes of gold(III). [32] We therefore explored synthetic routes to Au III complexes with [C 2 B 10 H 11 ] À and [2,2'-(C 2 B 10 H 10 ) 2 ] 2À ligands and report here the synthesis and structures of the first examples of well-characterised gold(III) dicarboranyl derivatives.…”

Section: Introductionmentioning

confidence: 99%

Do Gold(III) Complexes Form Hydrogen Bonds? An Exploration of Au^III Dicarboranyl Chemistry

Chambrier

Hughes

Jeans

et al. 2020

Chemistry A European J

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The reaction of 1,1'-Li 2 [(2,2'-C 2 B 10 H 10 ) 2 ]w ith the cyclometallated gold(III) complex( C^N)AuCl 2 afforded the first examples of gold(III) dicarboranyl complexes. The reactivity of these complexes is subject to the trans-influence exerted by the dicarboranyl ligand,w hichi ss ubstantially weaker than that of non-carboranyl anionic C-ligands. In line with this, displacemento fc oordinated pyridine by chloride is only possible under forcing conditions. While treatment of (C^N)Au{(2,2'-C 2 B 10 H 10 ) 2 }( 2)w ith triflic acid leads to AuÀC rather than AuÀNb ond protonolysis, aqueous HBr cleaves the AuÀNb ond to give the pyridinium bromo complex 7.The trans-influence of as eries of ligands including dicarboranyl and bis(dicarboranyl) was assessed by meansofD FT calculations. The analysis demonstrated that it was not suffi-cient to rely exclusively on geometricd escriptors (calculated or experimental) when attempting to rank ligands fort heir trans influence. Complex( C^N)Au(C 2 B 10 H 11 ) 2 containing two non-chelating dicarboranyll igandsw as prepared similar to 2.I ts reaction with trifluoroacetic acida lso leads to AuÀN cleavage to give trans-(Hpy^C)Au(OAc F )(C 2 B 10 H 11 ) 2 (8). In crystals of 8 the pyridiniumN ÀHb ond points towards the metal centre, while in 7 it is bent away.T he possible contribution of gold(III)···HÀNh ydrogen bonding in these complexes was investigated by DFT calculations. The results show that, unlike the situation for platinum(II), there is no evidencef or an energeticallys ignificant contribution by hydrogen bonding in the case of gold(III).

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“…There are many representatives of compounds containing three ligands and three metals forming triangular shapes (Figure ). Imidazolates with coinage metals, phenylene (most examples correspond to o ‐tetrafluorophenylene) with mercury, 1,2‐dicarba‐ closo ‐dodecaboranes with Au(I), and pyrazolates with coinage metals (e.g., Table ). As the present study deals with the last class of complexes that are often designed by [M(μ‐Py)] 3 , and only for Ag(I), we have reported structural papers dealing with them in Table .…”

Section: Introductionmentioning

confidence: 99%

An experimental and computational NMR study of organometallic nine‐membered rings: Trinuclear silver(I) complexes of pyrazolate ligands

Alkorta

Elguero

Dias

et al. 2020

Magnetic Reson in Chemistry

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This work reports the calculation of the nuclear magnetic resonance (NMR) chemical shifts of eight trinuclear Ag(I) complexes of pyrazolate ligands using the relativistic program ZORA. The data from the literature concern exclusively 1H, 13C, and 19F nuclei. For this reason, one of the complexes that is derived from 3,5‐bis‐trifluoromethyl‐1H‐pyrazole has been studied anew, and the 15N and 109Ag chemical shifts determined for the first time in solution. Solid‐state NMR data of this compound have been obtained for some nuclei (1H, 13C, and 19F) but not for others (14N, 15N, and 109Ag).

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Trinuclear Gold–Carborane Cluster as a Host Structure

Cited by 8 publications

References 40 publications

Hydrogen vs. Halogen Bonds in 1-Halo-Closo-Carboranes

Hydrogen vs. Halogen Bonds in 1-Halo-Closo-Carboranes

Do Gold(III) Complexes Form Hydrogen Bonds? An Exploration of Au^III Dicarboranyl Chemistry

An experimental and computational NMR study of organometallic nine‐membered rings: Trinuclear silver(I) complexes of pyrazolate ligands

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Trinuclear Gold–Carborane Cluster as a Host Structure

Cited by 8 publications

References 40 publications

Hydrogen vs. Halogen Bonds in 1-Halo-Closo-Carboranes

Hydrogen vs. Halogen Bonds in 1-Halo-Closo-Carboranes

Do Gold(III) Complexes Form Hydrogen Bonds? An Exploration of AuIII Dicarboranyl Chemistry

An experimental and computational NMR study of organometallic nine‐membered rings: Trinuclear silver(I) complexes of pyrazolate ligands

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Do Gold(III) Complexes Form Hydrogen Bonds? An Exploration of Au^III Dicarboranyl Chemistry