Unsaturation in binuclear cyclopentadienyliron carbonyl thiocarbonyls: Four-electron donor bridging thiocarbonyl groups versus metal-metal multiple bonds

Theoretical studies on the binuclear cyclopentadienyliron carbonyl thiocarbonyl derivatives Cp₂Fe₂(CO)₂(μ-CS)(μ-CO) and Cp₂Fe₂(CO)₂(μ-CS)₂ indicate that the trans and cis isomers are nearly degenerate in energy, consistent with experiment. Structures with bridging CS groups are of lower energy than corresponding structures with bridging CO groups. The corresponding unbridged Cp₂Fe₂(CS)(CO)₃ and Cp₂Fe₂(CS)₂(CO)₂ isomers are predicted to lie 11 and 16 kcal/mol, respectively, above their global minima, indicating increasing activation energies for the cis/trans interconversion as bridging CO groups are replaced by bridging CS groups. The unsaturated species Cp₂Fe₂(μ-CS)(μ-CO)₂ and Cp₂Fe₂(μ-CS)₂(μ-CO) are predicted to have triply bridged triplet spin state structures with FeFe double bonds of lengths 2.26 Å, analogous to the experimentally known triplet (Me₅C₅)₂Fe₂(μ-CO)₃. However, low-lying singlet Cp₂Fe₂(CS)(CO)₂ and Cp₂Fe₂(CS)₂(CO) structures with four-electron donor bridging η²-μ-CS groups and formal Fe-Fe single bonds are also found. The lowest lying Cp₂Fe₂(CS)(CO) and Cp₂Fe₂(CS)₂ structures have two bridging groups and very short FeFe distances of ∼2.14 Å, suggesting formal triple bonds. Several higher energy four-electron donor η²-μ-CS bridged structures are also found for Cp₂Fe₂(CS)(CO) and Cp₂Fe₂(CS)₂. In addition, singlet and triplet structures are found for Cp₂Fe₂(CS)₂ in which the two CS ligands have coupled to form a bridging SCCS group with a carbon-carbon bond. Only a η²-μ-CS bridged singlet structure is predicted for Cp₂Fe₂(CS), rather than the normal bridged structure with a FeFe quadruple bond such as that predicted for the carbonyl analog Cp₂Fe₂(CO).     

Synthesis and derivatization of halflanthanidocene aryl(alk)oxide complexes

The reaction of halflanthanidocene aryloxides Cp^R′Ln(OAr^tBu,R)₂ (Ln = Y, La, Lu; Cp^R′ = C₅Me₅, C₄Me₄H; R = H, Me) and halflanthanidocene alkoxides [(C₅Me₅)Ln(OCH₂CMe₃)₂]₂ (Ln = Y, Lu) with trimethylaluminum (TMA) was investigated. Monomeric Cp^R′Ln(OAr^tBu,R)₂, derived from the ortho-tBu-substituted OC₆H₂tBu₂-2,6-R-4 (R = H, Me) ligands, form mono(tetramethylaluminate) complexes Cp^R′Ln(OAr^tBu,R)(AlMe₄) for the smaller lanthanide metal centers yttrium and lutetium. Such an [aryloxide] → [aluminate] ligand exchange was not observed at the larger lanthanum metal center. The mobility of the tetramethylaluminate ligands of complexes Cp^R′Ln(OAr^tBu,R)(AlMe₄) (Ln = Y, Lu) was examined by variable-temperature (VT) ¹H NMR spectroscopy, revealing two signals for bridging and terminal methyl groups at lower temperatures. The treatment of complexes Cp^R′Ln(OAr^tBu,R)(AlMe₄) with donor solvent d₈-THF gave Cp^R′Ln(OAr^tBu,R)(Me)(d₈-THF)₂ (Ln = Y, Lu) with terminal methyl groups, according to a donor-induced aluminate cleavage reaction. Dimeric [(C₅Me₅)Ln(OCH₂CMe₃)₂]₂ (Ln = Y, Lu) was synthesized from (C₅Me₅)Ln(NiPr₂)₂(THF) and reacted with two equivalents of TMA per Ln center to yield monomeric bis(TMA) adduct complexes (C₅Me₅)Ln(OCH₂CMe₃)₂(AlMe₃)₂(Ln = Y, Lu). VT NMR spectroscopic studies confirmed a high mobility of the Ln(μ-OCH₂CMe₃)(μ-Me)AlMe₂ moieties at an ambient temperature. Both bis(TMA) adduct complexes were characterized by X-ray structure analysis.     

Structural comparison of (pentamethylcyclopentadienyl)iridium(III) azido complexes containing potentially N,S-bidentate N-heterocyclic thiolates: 2- or 8-quinolinethiolate and benzimidazole-2-thiolate

The crystal structures of mononuclear (azido)(pentamethylcyclopentadienyl)iridium(III) complexes bearing 2- or 8-quinolinethiolate (n-Sqn⁻), [Cp^∗Ir(N₃)(n-Sqn)] {n = 2 (1) or 8 (2); Cp^∗ = η⁵-C₅Me₅} have been determined by X-ray analysis. The 2-Sqn complex, 1, acquires severe steric strains in the four-membered κ²N,S chelate ring, while the 8-Sqn isomer, 2, forms a strain-free five-membered planar κ²N,S chelate ring. It has also been revealed that the corresponding benzimidazole-2-thiolate (Hbimt⁻) complex, which was obtained similarly to the above n-Sqn complexes from [Cp^∗Ir(N₃)₂]₂ and Na(Hbimt), takes an unsymmetrical dinuclear structure bridged by two Hbimt⁻ ligands with different bonding modes, [Cp^∗Ir(N₃){μ(S:N¹)-Hbimt}{μ(S:S)-Hbimt}Ir(N₃)Cp^∗] · MeOH (3).     

Interactions of molybdocene dichloride with histidine- and methionine-containing peptides

The reaction behavior of the antitumor active metallocene dihalide Cp₂MoCl₂ (Cp = η⁵-cyclopentadienyl) towards AcHis, AcHis(1-Me), AcHis(3-Me), His-Gly, AcHis-Gly-His, AcMet, Gly-Met-Gly and cyclo-Met-Met has been studied in solution at 2.5 ? pD ? 7.4 by using ¹H NMR spectroscopy. The histidine-containing substrates were found to bind the Cp₂Mo²⁺ unit through the terminal carboxylate group or through the N1 nitrogen of the imidazole ring, depending on the pD value. At physiological pH, coordination takes place exclusively at the imidazole ring with the percentage of Cp₂Mo²⁺-His adducts in 1:1 mixtures being about 70%. By contrast, the thioether group in the side chain of methionine has a very low affinity for the Cp₂Mo²⁺ group. Monodentate S-coordination could not be detected. For AcMet, binding through the carboxylate group was observed as the only coordination mode, while in the case of Gly-Met-Gly Mo-S interaction occurs in combination with carboxylate coordination leading to a S,O-macrochelate in low yield. Coordination to methionine peptides only takes place at pD ? 6, while at physiological pH interactions with the weak donor sites are not observed due to predominating dimerization of [Cp₂Mo(H₂O)(OH)]⁺ to [Cp₂Mo(μ-OH)₂MoCp₂]²⁺. At c(Cl⁻) = 100 mM competitive Cl⁻ coordination reduces the amount of carboxylate and S,O-coordination significantly, while imidazole coordination is not affected.     

Macropolyhedral boron-containing cluster chemistry : Products of the reaction between [{Ru(η-MeC6H4Pr)Cl2}2] and syn-[B18H22]. A syn → anti 18-vertex configurational change

Reaction of [{RuCl₂(η⁶-MeC₆H₄^isoPr)}₂] with syn-[B₁₈H₂₂] and non-nucleophilic base results in [8-(η⁶-MeC₆H₄^isoPr)-8-RuB₁₇H₂₁], of 18-vertex anti 10-vertex-nido-10-vertex-nido configuration, as the predominant product. The syn → anti configurational change arises from a trans-cluster pseudo-vertex-substitution of a {BH} vertex by the {Ru₂(η⁶-MeC₆H₄^isoPr)} centre.     

Electronic structure of a benzylidyne-capped tricobalt cluster, [Co3Cp3(μ3-CPh)2]. X-ray structures and H NMR paramagnetic shifts of its cation and DFT calculations of its model complex

The cationic tricobalt cluster [Co₃Cp₃(μ₃-CPh)₂]⁺ (1⁺) was synthesized by the electrochemical oxidation of [Co₃Cp₃(μ₃-CPh)₂] (1). A large structural change was observed not only in the Co-Co, but also in the Co-C(cap) bonds upon oxidation of 1 to 1ClO₄. ¹H NMR paramagnetic shifts of this salt were measured in CD₂Cl₂. The π spin density on each sp² carbon atom was estimated to be 0.0089 (o-Ph), −0.0012 (m-Ph), 0.0087 (p-Ph), and 0.0053 (Cp). These values on the phenyl carbon atoms are similar to ca. 1/25 of those of the benzyl radical. It indicates that there is significant spin density on the capping carbon atom, which is delocalized onto the benzylidyne groups from the Co₃C₂ oxidation center by π conjugation between them. These results are consistent with the e^′′ (in the idealized D_3h symmetry) singly occupied molecular orbital (SOMO) of 1⁺, and are reproduced by B3LYP-DFT calculations of a model complex, [Co₃Cp₃(μ₃-CH)₂] (2), and its cation.     

Hydride transfer from transition metal hydrides to dihapto acyl ligands

The dihapto acyl ligand in Cp₂Zr[C(O)R]X, (R = Me, Ph; X = Me, Cl) is subject to hydrogen transfer from Cp₂MH₂ (M = Mo, W), Cp₂ReH and CpReH₄(PMe₂Ph). The initial products are bimetallic dimers of the type Cp₂XZrOCH(R)ML_n. The fate of this bimetallic species is highly dependent upon the Group VIB metal when Cp₂MH₂ is the hydride source. For M = Mo, a second hydrogen migrates to the acyl carbon, yielding Cp₂Zr(OEt)Me and products derived from Cp₂Mo. For M = W, CO bond scission occurs with retention of the WC bond, to yield the carbene complexes Cp₂WC(C)R along with various oxyzirconium products. Filled d orbitals are not necessary on the hydride source; Cp₂NbH₃ also readily reduces the acyl in Cp₂Zr[C(O)Me]Me.     

Reaction behavior of molybdocene dichloride towards ribonucleosides and ribonucleoside monophosphates: Rare example of sugar coordination

The coordination behavior of Cp₂Mo²⁺ towards the ribonucleosides and ribonucleoside monophosphates uridine, adenosine, cytidine, guanosine, 5′-UMP, 5′-AMP, 5′-CMP and 5′-GMP has been studied in solution in the range 4 ? pD ? 9 using NMR spectroscopy. The ribonucleosides were found to bind Cp₂Mo²⁺ exclusively through the ribose moiety giving rise to the chelate complexes [Cp₂Mo(urd-O2′,O3′)], [Cp₂Mo(ade-O2′,O3′)], [Cp₂Mo(cyd-O2′,O3′)], and [Cp₂Mo(gua-O2′,O3′)]. The ribonucleotides form three types of complex with Cp₂Mo²⁺ in neutral solution, namely N,PO-macrochelates, PO,O3′-coordinated species as well as O2′,O3′-chelates, while at pD 9 only sugar coordination is observed.     

Structural and activity changes in three bioactive anuran peptides when Asp is replaced by isoAsp

The Asp and isoAsp isomers of three bioactive peptides, Crinia angiotensin 11 [APGDRIYHPF(OH)], uperin 1.1 [pEADPNAFYGLM(NH₂)] and citropin 1.1 [GLFDVIKKVASVIGGL(NH₂)] were tested for changes in (i) susceptibility towards proteolytic cleavage, (ii) activity (smooth muscle activity for Crinia angiotensin 11 and uperin 1.1 isomers, and antimicrobial activity for the two isomers of citropin 1.1), and (iii) 3D structures in water, trifluoroethanol-d₃/water (1:1) and DPC micelles as determined by 2D nuclear magnetic resonance spectroscopy. Proteolytic cleavage with trypsin was identical for each pair of Asp/isoAsp isomers. Cleavage with chymotrypsin was the same for the Crinia angiotensin and uperin 1.1 isomeric pairs, but different for the two Asp/isoAsp citropin 1.1 isomers. Chymotrypsin cleaved at Phe3 (adjacent to Asp4) for citropin 1.1, but not at Phe3 (adjacent to isoAsp4) for isoAsp citropin 1.1. The smooth muscle activity of the isoAsp isomer of Crinia angiotensin 11 was less than that of the Asp isomer. The smooth muscle activity of isoAsp3-uperin 1.1 is greater than that of the Asp isomer at low concentration (<10⁻⁹ M) but no different from the Asp isomer at concentrations > 10⁻⁹ M. Citropin 1.1 is a wide-spectrum antibiotic against Gram positive organisms, while the isoAsp isomer is inactive against the test pathogens Staphylococcus aureus and Bacillus subtilis. The observed changes in activity are accompanied by changes in the 3D structures of isomers as determined by 2D nuclear magnetic resonance spectroscopy.     

Crystal structure, optical, magnetic, and photochemical properties of the complex pentakis(dimethyl sulfoxide)nitrosylchromium(2+) hexafluorophosphate

The nitrosyl complex [Cr(dmso)₅(NO)](PF₆)₂ (1) (dmso = dimethyl sulfoxide) has been prepared by the solvolysis of [Cr(NCCH₃)₅(NO)](PF₆)₂ in neat dmso. The optical absorption spectrum of 1 in dmso shows maxima at 734, 567, 450, 413, and 337 nm. Continuous photolysis of 1 with λ = 365-580 nm light in dmso solution results in a release of NO with quantum yield, Φ, in the range 0.034-0.108 mol Einstein⁻¹. Irradiation of a deoxygenated CH₃CN solution of [Cr(NCCH₃)₅(NO)](PF₆)₂ in the presence of excess of [Fe(S₂CNEt₂)₂] results in a transfer of NO to the iron centre as shown from the characteristic EPR spectrum of [Fe(S₂CNEt₂)₂(NO)] with A_iso(¹⁴N) = 12.2 × 10⁻⁴ cm⁻¹. The EPR parameters of 1 were determined: g_iso, g_‖ and g_⊥ : 1.96725, 1.91881(4) and 1.992763(2); A_iso(⁵³Cr), A_‖ (⁵³Cr) and A_⊥(⁵³Cr): 22.8 × 10⁻⁴, 39 × 10⁻⁴ and 15.8 × 10⁻⁴ cm⁻¹; A_iso(¹⁴N), A_‖ (¹⁴N) and A_⊥(¹⁴N): 5.9 × 10⁻⁴, 2 × 10⁻⁴ and 7.540(4) × 10⁻⁴ cm⁻¹.     

High-spin binuclear cyclopentadienyliron chlorides: a density functional theory study

Theoretical studies on the cyclopentadienyliron chlorides Cp₂Fe₂Cl _n (n?=?6???1) with iron in the formal oxidation states from +1 to +4 indicate that all the high-spin species are predicted to be the lowest energy structures and they are paramagnetic complexes with magnetic moments between 2.8μ _B and 5.9μ _B. The mixed oxidation state derivatives with odd number of chloride atoms have larger magnetic moments than other species. In addition to Cp₂Fe₂Cl, which has the largest magnetic moment, these high-spin species have terminal Cp rings and bridging Cl atoms up to a maximum of two bridges. The Cp₂Fe₂Cl₄, Cp₂Fe₂Cl₃ and Cp₂Fe₂Cl₂ derivatives are predicted to be thermodynamically stable molecules with respect to exothermic reactions for the loss of one Cl atom from Cp₂Fe₂Cl _n . Moreover, the lowest energy Cp₂Fe₂Cl _n (n?=?3, 4) derivatives can be derived by the oxidative addition reactions of Cp₂Fe₂Cl _n?2 + Cl₂ → Cp₂Fe₂Cl _n .

Natural bond orbital, nuclear magnetic resonance analysis and hybrid-density functional theory study of σ-aromaticity in Al2F6, Al2Cl6, Al2Br6 and Al2I6

Natural bond orbital (NBO), nuclear magnetic resonance (NMR) analysis and hybrid-density functional theory based method (B3LYP/Def2-TZVPP) were used to investigate the correlation between the nucleus-independent chemical shifts [NICS, as an aromaticity criterion], σ _Al(1)-X2(b) → σ*_Al(3)-X4(b) electron delocalizations and the dissociation energies of Al₂F₆, Al₂Cl₆, Al₂Br₆ and Al₂I₆ to 2AlX₃ (X?=?F, Cl, Br, I). The results obtained showed that the dissociation energies of Al₂F₆, Al₂Cl₆, Al₂Br₆ and Al₂I₆ decrease from Al₂F₆ to Al₂I₆. Like aromatic molecules, these compounds have relatively significant negative NICS_iso(0) values. Clearly, based on magnetic criteria, they exhibit aromatic character and make it possible to consider them as σ-delocalized aromatic species, such as Möbius σ-aromatic species. The σ-aromatic character which is demonstrated by their NICS_iso(0) values decreases from Al₂F₆ to Al₂I₆. The NICS_iso values are dominated by the in-plane σ₂₂ (i.e., σ_yy, the plane containing halogen atoms bridged) chemical shift components. The increase of the NICS_iso values explains significantly the decrease of the corresponding dissociation energies of Al₂F₆, Al₂Cl₆, Al₂Br₆ and Al₂I₆. Importantly, the NBO results suggest that in these compounds the dissociation energies are controlled by the stabilization energies associated with σ _Al(1)-X2(b) →σ*_Al(3)-X4(b) electron delocalizations. The decrease of the stabilization energies associated with σ _Al(1)-X2(b) →σ*_Al(3)-X4(b) electron delocalizations is in accordance with the variation of the calculated NICS_iso values. The correlations between the dissociation energies of Al₂F₆, Al₂Cl₆, Al₂Br₆ and Al₂I₆, σ _Al(1)-X2(b) →σ*_Al(3)-X4(b) electron delocalizations, natural atomic orbitals (NAOs) and NICS_iso values have been investigated.     

Synthesis of cyclopentadienyl gadolinium and samarium alkoxide complexes

The mixed ligand complexes [{Gd(OCMe₂-i-Pr)₂Cp}₂], [{Sm(OCMe₂-i-Pr)₂Cp}₂], and [Sm₂(OCMe₂-i-Pr)₃Cp₃] were synthesized by reacting [LnCp₃] with HOCMe₂-i-Pr. X-ray crystallographic studies show that the three complexes each have two bridging alkoxide ligands linking two metal atoms. The coordination geometries at the metals are distorted tetrahedral.     

Optical and EPR spectra of the thionitrosyl complex [Cr(OH2)5(NS)]

The green thionitrosyl complex [Cr(OH₂)₅(NS)]²⁺ was isolated in solution by the hydrolysis of [Cr(NCCH₃)₅(NS)]²⁺. The optical absorption spectra of both compounds are dominated by a band with vibrational progression around 600 nm assigned as a {d_yz,zx, π^∗(NS)} → {π^∗(NS), d_yz,zx}^∗ transition. The optical data indicate that the NS ligand is a weaker π-acceptor than the NO ligand. The EPR parameters of [Cr(OH₂)₅(NS)]²⁺ were determined: g_iso, g_∥ and g_⊥: 1.96515, 1.92686(5) and 1.986860(8); A_iso(⁵³Cr), A_∥(⁵³Cr) and A_⊥(⁵³Cr): 25.3 × 10⁻⁴, 38 × 10⁻⁴ and 18.5 × 10⁻⁴ cm⁻¹; A_iso(¹⁴N), A_∥(¹⁴N) and A_⊥(¹⁴N): 6.5 × 10⁻⁴, 2.81 × 10⁻⁴ and 8.346(12) × 10⁻⁴ cm⁻¹.     

Manganese(III) and rhenium(II) complexes with bulky 4,6-di-tert-butyl-N-(2,6-di-iso-propylphenyl)-o-iminobenzoquinonato ligands via carbonyls of corresponding metals

Four-coordinate complex Mn^III(ISQ-Prⁱ)(AP-Prⁱ) (1), where ISQ-Prⁱ = 4,6-di-tert-butyl-N-(2,6-di-iso-propylphenyl)-o-iminobenzosemiquinonate anion-radical, AP-Prⁱ = 4,6-di-tert-butyl-N-(2,6-di-iso-propylphenyl)-o-amidophenolate dianion, has been prepared by the reaction of Mn₂(CO)₁₀ with free 4,6-di-tert-butyl-N-(2,6-di-iso-propylphenyl)-o-iminobenzoquinone (IBQ-Prⁱ) in the molar ratio 1:4 in toluene. In contrast to manganese, rhenium carbonyl reacts with o-iminobenzoquinone to form complex Re^II(ISQ-Prⁱ)₂(CO)₂ (2) with the retention of two carbonyls in coordination sphere of rhenium. The complexes have been characterized by IR, UV-Vis, and EPR spectroscopies. Molecular structures of compounds 1 and 2 have been determined by single-crystal X-ray crystallography. Compound 1 is centro-symmetric square-planar molecule with delocalized mixed valent state of AP-Prⁱ and ISQ-Prⁱ ligands. EPR spectrum of 1 in solid at 300-77 K is typical for manganese complexes with S = 3/2 state. The effective magnetic moment of 1 is 1.96 μ_B at temperature 5 K as it was established by variable-temperature magnetic susceptibility measurements. Six-coordinate octahedral complex 2 possesses an S = 1/2 ground state, which is attained via strong intramolecular antiferromagnetic interaction between t_2g orbital unpaired electron of the low spin Re^II ion and the unpaired electron on π-orbital of the radical ligand.     

Aqueous Speciation of ansa- and non-ansa- Substituted [Cp2Mo(μ-OH)]2[OTs]2

Titration curves were measured for three molybdocene dimers, [Cp₂Mo(μ-OH)]₂[OTs]₂ (4), [Mo(μ-OH)]₂[OTs]₂ (4′; Cp′ = C₅H₄CH₃), and ansa-[C₂Me₄Cp₂Mo(μ-OH)]₂[OTs]₂ (4^a), and for two monomeric molybdocene complexes, Cp₂MoO (6) and Cp₂MoCl₂ (1). The titration curves for 4, 6, and 1 were identical and showed three equivalence points each. The titration curve for 4′ was also similar in appearance but the equivalence points were shifted higher by ∼0.3, as expected for the more electron-rich Mo center in this molecule. The titration curve for the ansa-[C₂Me₄Cp₂Mo(μ-OH)]₂[OTs]₂ complex showed only two equivalence points. Two of the equivalence points observed in the titration of 4, 6, and 1 were previously reported in potentiometric measurements of aqueous solutions of Cp₂MoCl₂ and were attributed to the Cp₂Mo(OH₂)²⁺ species (pK_a = 5.5 ± 0.1 and 8.3 ± 0.2). The third equivalence point (pK_a = 2.2 ± 0.2) is assigned to protonation/deprotonation of the [Cp₂Mo(μ-OH)]₂[OTs]₂/[Cp₂Mo(μ-OH₂)(μ-OH)MoCp₂]³⁺ dimer. A new equilibrium scheme is proposed for the aquated molybdocenes to provide a more complete picture of the aqueous speciation of the non-ansa molybdocene complexes, specifically by accounting for the third acidic proton in the titration curves and by describing the hydrolysis of Cp₂MoO. Although the titration curve of the ansa-[C₂Me₄Cp₂Mo(μ-OH)]₂[OTs]₂ complex is different from that of [Cp₂Mo(μ-OH)]₂[OTs]₂, ¹H NMR data suggest that the aqueous speciation of the ansa-[C₂Me₄Cp₂Mo(μ-OH)]₂[OTs]₂ complex is analogous to that of the non-ansa molybdocenes.     

Direct Evidence for Nitrogen Ligation to the High Stability Semiquinone Intermediate in Escherichia coli Nitrate Reductase A

The membrane-bound heterotrimeric nitrate reductase A (NarGHI) catalyzes the oxidation of quinols in the cytoplasmic membrane of Escherichia coli and reduces nitrate to nitrite in the cytoplasm. The enzyme strongly stabilizes a menasemiquinone intermediate at a quinol oxidation site (Q_D) located in the vicinity of the distal heme b_D. Here molecular details of the interaction between the semiquinone radical and the protein environment have been provided using advanced multifrequency pulsed EPR methods. ¹⁴N and ¹⁵N ESEEM and HYSCORE measurements carried out at X-band (∼9.7 GHz) on the wild-type enzyme or the enzyme uniformly labeled with ¹⁵N nuclei reveal an interaction between the semiquinone and a single nitrogen nucleus. The isotropic hyperfine coupling constant A_iso(¹⁴N) ∼0.8 MHz shows that it occurs via an H-bond to one of the quinone carbonyl group. Using ¹⁴N ESEEM and HYSCORE spectroscopies at a lower frequency (S-band, ∼3.4 GHz), the ¹⁴N nuclear quadrupolar parameters of the interacting nitrogen nucleus (κ = 0.49, η = 0.50) were determined and correspond to those of a histidine N_δ, assigned to the heme b_D ligand His-66 residue. Moreover S-band ¹⁵N ESEEM spectra enabled us to directly measure the anisotropic part of the nitrogen hyperfine interaction (T(¹⁵N) = 0.16 MHz). A distance of ∼2.2 Åbetween the carbonyl oxygen and the nitrogen could then be calculated. Mechanistic implications of these results are discussed in the context of the peculiar properties of the menasemiquinone intermediate stabilized at the Q_D site of NarGHI.     

Halide abstraction reactions of Sb(V) chloride: Synthesis and characterisation of hexachloroantimonate salts of M(II) M = Zn,Mg; M(III) M = Cr; and M(IV) M = Ti,Sn and related Cp2M(IV) M = Ti,Zr and Hf

Reactions of SbCl₅ with various covalent metal halides in MeCN have been studied as a convenient and direct route to metal hexachloroantimonate salts via Sb(V) halide abstraction. The isolation and characterization (Ir, Vis-UV, ¹H NMR spectroscopic and microanalytical) of the complexes [Zn(MeCN)₆][SbCl₆]₂, [CrCl₂(MeCN)₄][SbCl₆], [SnCl₃(MeCN)₃][SbCl₆], [TiCl₂(MeCN)₄][SbCl₆]₂, [Cp₂M(Cl)(MeCN)_x][SbCl₆] M = ti, x = 1; M = Zr, Hf, x = 2, and [Cp₂M(MeCN)_y][SbCl₆]₂ M = Ti, y = 2; M = Zr, Hf, y = 3, is described. The reaction of MgCl₂ with SbCl₅ was carried out in EtOAC as solvent and gave [Mg(EtOAc)₆][SbCl₆]₂. ¹²¹Sb NMR, IR and UV spectroscopic measurements provide positive identification of the SbCl_6⁻ anion.     

Monodentate, didentate chelating, and bridging 1,8-naphthyridine complexes of pentamethylcyclopentadienyliridium(III): Syntheses and structures in the solid states and in solution

A series of new iridium(III) complexes containing pentamethylcyclopentadienyl (Cp^∗ = η⁵-C₅Me₅) and 1,8-naphthyridine (napy) have been prepared. X-ray crystallography revealed that napy acted as a monodentate, a didentate chelating, and a bridging ligand in complexes of [Cp^∗IrCl₂(napy)] (1), [Cp^∗IrCl(napy)]PF₆ (2), and [(Cp^∗IrCl)₂(H)(napy)]PF₆ (4), respectively. The crystal structure of [Cp^∗Ir(napy)₂](PF₆)₂ (3) has also been determined; the dicationic complex bore both monodentate and chelating napy ligands. Dinuclear Cp^∗Ir^III complex bridged by napy was only isolable if two Ir^III centers were supported by a hydride (H⁻) bridge. In complexes 2 and 3, the four-membered chelate rings formed by napy exhibited a large steric strain; in the rings the NIrN bond angles were only 60.5(2)-61.0(4)° and the IrNC angles were 94.7(8)-96.7(8)°. The bridging coordination of napy in complex 4 also afforded a large strain, i.e., the Ir^III centers were displaced by 0.84(3) Å from the napy plane, due to the steric interaction between two Cp^∗IrCl moieties. The monodentate napy complex 1 in CDCl₃ or CD₂Cl₂ at ambient temperature showed a rapid coordination-site exchange reaction, which gave two N sites of napy equivalent; at temperatures below −40 °C, the ¹H NMR spectra corresponded to the molecular structure of [Cp^∗IrCl₂(napy-κN)]. The analogous diazido complex of [Cp^∗Ir(N₃)₂(napy)] (5) has also been prepared, and the crystal structure has been determined. In contrast to the dichloro complex 1, the diazido complex 5 exhibited a dissociation equilibrium of coordinated napy in solution.     

Ring folding in cyclopentadienyl diazabutadiene complexes of group 4 and 5 transition metals

The syntheses of CpM(i-PrDAB)₂ (M = Nb, Ta; Cp = (C₅H₅); i-PrDAB = bis-isopropyl-1,4-diazabuta-1,3-diene) are reported. Both show fluxional NMR spectra indicating that the two DAB rings differ. The X-ray crystal structure of CpNb(i-PrDAB)₂ shows one ring to be more folded than the other. Density functional calculations have been used to investigate the degree of folding of the chelate ring in the compounds Cp₂M(R-DAB), (M = Ti, Zr, Hf, Nb, Ta; R = H, i-Pr; DAB = 1,4-diazabuta-1,3-diene) and CpM(R-DAB)₂ (M = Nb and Ta). For Cp₂M(R-DAB) the group 4 compounds all have folded rings whereas the Nb and Ta compounds have planar rings. In all compounds the rings are reduced and the folding is driven by the electron number requirements of the metal centre.