Density functional theory studies on a designed photoactive {FeNO} nitrosyl and the corresponding photoinactive {FeNO} species: Insight into the origin of NO photolability

Density functional theory (DFT) and time-dependent DFT (TDDFT) studies on a photoactive {FeNO}⁶ nitrosyl [(PaPy₃)Fe(NO)](ClO₄)₂ (1) and the corresponding light-insensitive {FeNO}⁷ species [(PaPy₃)Fe(NO)](ClO₄) (2) have been carried out to determine the origin of NO photolability of 1. The iron center in these two nitrosyls formally exists in 2+ oxidation state and the difference in π-accepting ability of NO⁺ in 1 versus NO in 2 greatly affects the extent of NO photolability of these two nitrosyls. Low energy transitions from the carboxamido/π(FeNO) to the FeNO antibonding molecular orbitals lead to release of NO from 1 upon exposure to visible light. The decreased π-accepting ability of the NO moiety in 2 does not favor such transitions; instead transitions from orbitals centered at the FeNO unit to the π_py orbitals of the ligand frame become more favorable and the photolability of NO is lost in 2.     

Synthesis and characterization of a dinuclear Ni complex containing a bridging CNC pincer ligand

The reaction of the bis(carbene) pincer ligand ^MeCNC with nickel acetate and Bu₄NBr produced [(^MeCNC)₃Ni₂]⁴⁺[Br]₄ (2), a complex that contains the ^MeCNC ligand in both traditional tridentate chelating modes as well as in a unique, bridging mode between two Ni²⁺ ions. While 2 could not be crystallized or isolated in a pure form, the anion exchange of bromide with triflate yielded [(^MeCNC)₃Ni₂]⁴⁺[OTf]₄ (4), which could be recrystallized from methanol and isolated pure. Single-crystal X-ray analysis of 4 confirmed the unusual dual-coordination modes of the ^MeCNC ligand towards Ni²⁺ in these species, and represents the initial example of a Group 10 complex of a bridging CNC ligand.     

Structural variety and stereochemical features of bis(diphenylphosphinyl)[3]ferrocenophane gold(I) complexes

The P,N-[3]ferrocenophane ligand 3 forms a (κP-ligand)AuCl complex (5) upon treatment with (Me₂S)AuCl. The corresponding P,P-[3]ferrocenophane system 4 yields a binuclear (κP,κP-chelate ligand)(AuCl)₂ complex (6) when reacted with 2 equivalents of the (Me₂S)AuCl reagent. Complex 6 features an intramolecular aurophilic Au?Au interaction. Treatment of the P,P-[3]ferrocenophane 4 with 1.0 equiv. of (PPh₃)AuCl gives the tetra-coordinated mono-gold(I) complex (P,P-ligand)(PPh₃)AuCl (7), whereas the cationic [(P,P-ligand)₂Au]⁺[Cl⁻] system is obtained from 4 and 0.5 equivalents of (Me₂S)AuCl. The [(P,P-ligand)₂Au]⁺ system is obtained in different diastereoisomeric forms (8 and 9) depending on the stereochemistry of the pair of P,P-[3]ferrocenophane chelate ligand used. Examples of the complexes 5, 6, 7 and 8 were characterized by X-ray diffraction.     

Synthesis and characterization of cobalt(II)-salicylate complexes derived from N4-donor ligands: Stabilization of a hexameric water cluster in the lattice host of a cobalt(III)-salicylate complex

The syntheses and structural characterization of four cobalt(II)-salicylate complexes, [(TPA)Co^II(HSA)](ClO₄) (1), [(isoBPMEN)Co^II(HSA)](BPh₄) (2), [(TPzA)Co^II(HSA)](ClO₄) (3) and [(6Me₃TPA)Co^II(HSA)](BPh₄) (4) [TPA = tris(2-pyridylmethyl)amine, isoBPMEN = N¹,N¹-dimethyl-N²,N²-bis(2-pyridylmethyl)ethane-1,2-diamine, TPzA = tris((3,5-dimethyl-1H-pyrazole-1-yl)methyl)amine and 6Me₃TPA = tris(6-methyl-2-pyridylmethyl)amine] are described. While 2, 3 and 4 are unreactive towards dioxygen, 1 reacts slowly with molecular oxygen to a cobalt(III)-salicylate complex, [(TPA)Co^III(SA)](ClO₄) (1a). Two different crystalline forms, 1a and 1a·4H₂O were isolated depending upon the condition of oxidation and crystallization. The solid-state structures of cobalt(III)-salicylate unit in both 1a and 1a·4H₂O show a six-coordinate distorted octahedral coordination geometry at the cobalt(III) center ligated by the tetradentate ligand (TPA) where the dianionic salicylate (SA) binds in a bidentate fashion through one carboxylate and one phenolate oxygen. The hydrated form 1a·4H₂O reveals a hexameric water cluster formation in the inorganic lattice host. The complex cation and the perchlorate counterion are involved in stabilizing the (H₂O)₆ cluster in a rare ‘pentamer planar+1’ conformation. A one-dimensional water tape consisting of edge-shared water hexamers is observed. The water tape represents a subunit of ice structure.     

Synthesis and characterization of sterically hindered tris(pyrazolyl)borate Ni complexes

Addition of KTp^Ph2 to a solution of NiX₂ (X = Cl, Br, NO₃, OAc and acac) or NiBr(NO)(PPh₃)₂ in THF yields the structurally characterized series [NiCl(Hpz^Ph2)Tp^Ph2] (1) and [NiXTp^Ph2] (X = Br 2, NO 3, NO₃4, OAc 5 and acac 6) including the first example of a tris(pyrazolyl)borate nickel nitrosyl complex. IR spectroscopy confirms that all the Tp^Ph2 ligands are κ³ coordinated and that the NO ligand in 3 is linearly bound. Electronic spectra are consistent with four- or five-coordinate species in solution. NMR spectroscopic studies indicate that the complexes are paramagnetic, with the exception of 3. This is confirmed by magnetic susceptibility studies, which suggest that complexes 1, 2 and 4-6 are paramagnetic with two unpaired electrons. X-ray crystallographic studies of 5 reveal a distorted trigonal bipyramidal nickel centre with a symmetrically coordinated acetate ligand.     

Unexpected reactivity resulting from modifications of the ligand periphery: Synthesis, structure, and spectroscopic properties of iron complexes of new tripodal N-heterocyclic carbene (NHC) ligands

The chelating ligand tris-[2-(3-aryl-imidazol-2-ylidene)ethyl]amine (TIMEN^R, R = aryl = 2,6-xylyl (xyl), mesityl (mes)) has provided access to reactive transition metal complexes. Here, two new tripodal N-heterocyclic carbene ligands of the TIMEN^R system (R = aryl = tolyl (tol), 3,5-xylyl (3,5xyl)), featuring sterically less demanding aryl substituents were synthesized. With these ligands, Fe(II) precursor complexes could be obtained, namely [(TIMEN^tol)Fe](BF₄)₂ (3) and [(TIMEN^3,5xyl)Fe(CH₃CN)](PF₆)₂ (7), which showed unexpected reactivity upon reduction. Treatment of the compounds with sodium amalgam yield the tris- and bis-metallated products, [(TIMEN^tol∗∗∗)Fe] (4) and [(TIMEN^3,5xyl∗∗)Fe] (8), respectively. While the Fe(III) complex 4 is relatively inert towards oxygen, the Fe(II) complex 8 is prone to oxidation. This oxidation of 8 can readily be observed in chlorinated solvents, producing the Fe(III) complex [(TIMEN^3,5xyl∗∗)Fe](PF₆) (9). All new ligand imidazolium precursors and metal complexes were characterized by single crystal X-ray structure determination.     

Syntheses, structures and magnetic properties of heterobimetallic complexes based on a new tetracyanometalate precursor

A new mononuclear tetracyanometallic complex, (n-Bu₄N)[(dbphen)Fe(CN)₄] (1, dbphen = 5,6-dibromo-1,10-phenanthroline), has been prepared by reacting [(dbphen)Fe^II(py)₂(SCN)₂] and KCN in water and further oxidized with chlorine. With the use of 1 as building block, two trinuclear Fe₂M complexes, [(dbphen)₂Fe₂(CN)₈Cu(Me₃tacn)]·3H₂O (2), [(dbphen)₂Fe₂(CN)₈Ni(dabhctd)]·2H₂O (3) and a chain complex of squares [(dbphen)₂Fe₂(CN)₈Co(MeOH)₂]_n (4), have been synthesized and structurally characterized. Magnetic studies show ferromagnetic coupling between Fe^III and M^II (M = Cu, 2; Ni, 3) ions bridged by cyanides in complexes 2 and 3, while complex 4 exhibits meta-magnetic behavior.     

Homo- and heteronuclear complexes based on arene ruthenium complexes bearing bis(diphenylphosphinomethyl)phenylphosphine (dpmp)

Reactions of [(p-cymene)RuCl₂]₂ (1a) with dpmp ((Ph₂PCH₂)₂PPh) in the absence or presence of KPF₆ afforded the ionic complexes [{(p-cymene)RuCl₂}(dpmp-P¹,P³;P²){RuCl(p-cymene)}](X) (2a₁: X=Cl; 2a₂: X=PF₆). A (p-cymene)RuCl moiety constructs a 6-membered ring coordinated by two terminal P atoms of the dpmp ligand and another one binds to a central P atom of the ligand. Reactions of [(C₆Me₆)RuCl₂]₂ (1b) with an excess of dpmp in the presence of KPF₆ gave a 4-membered complex [(C₆Me₆)RuCl(dpmp-P¹,P²)](PF₆) (3b), chelated by a terminal and a central P atom and another terminal atom is free. Use of Ag(OTf) instead of KPF₆ gave [{(C₆Me₆)RuCl₂(dpmp)Ag} ₂](OTf)₂ (5b) that the Ag atoms were coordinated by a terminal and a central P atom of each dpmp ligand. Reaction with an equivalent of dpmp in the presence of KPF₆ gave [{(C₆Me₆)RuCl}(dpmp-P¹,P²;P³){(C₆Me₆)RuCl₂}](PF₆) 4b. Complex has a structure that the (C₆Me₆)RuCl₂ moiety coordinated to the free P atom of 3b. Complex 3b was treated with MCl₂(cod) (M=Pd, Pt), [Pd(MesNC)₄](PF₆)₂ (MesNC=2,4,6-Me₃C₆H₂NC) or [Pt₂(XylNC)₆](PF₆)₂ (XylNC=2,6-Me₂C₆H₃NC), generating [{(C₆Me₆)RuCl(dpmp)}₂MCl₂](PF₆)₂ (8b: M=Pd; 9b: M=Pt), [{(C₆Me₆)RuCl(dpmp)}₂{Pt(MesNC)₂}](PF₆)₄ (10b) and [{(C₆Me₆)RuCl(dpmp)}₂{Pt₂(XylNC)₄}](PF₆)₄ (11b), respectively. Complex 3b reacted readily with [Cp*MCl₂]₂ (M=Rh, Ir) or AuCl(SC₄H₈), affording the corresponding hetero-binuclear complexes [{(C₆Me₆)RuCl}(dpmp-P¹,P²;P³)(MCl₂Cp^*](PF₆) (6b: M=Rh; 7b: M=Ir) and [{(C₆Me₆)RuCl}(dpmp-P¹,P²;P³)(AuCl)](PF₆) (12b). These complexes have two chiral centers. Some complexes were separated as two diastereomers by successive recrystallization. The structures of 3b, 5b, 6b, 8b and 12b were confirmed by X-ray analyses.     

Heteroleptic lanthanide terphenyl/tris(pyrazolyl)borate compounds of ytterbium

The synthesis and structural characterization of the two novel unsolvated heteroleptic ytterbium compounds DanipYb(Tp^Me,Me)Cl (1) and DanipYb(Tp^Me,Me)CH₂SiMe₃ (2) by simple salt metathesis reaction is reported [Danip = 2,6-di(o-anisol)phenyl); Tp^Me,Me = hydrotris(3,5-dimethyl-pyrazolyl)borate]. In the molecular structure of 2 a flexible bonding mode of the donor-functionalized terphenylic ligand is observed.     

Structural comparison of alkylated derivatives of (bmmp-dmed)Ni and (bmmp-dmed)Zn

The sulfur-alkylation of the nickel (1) and zinc (2) complexes of the dithiolate N₂S₂ ligand N,N′-bis-2-methyl-mercaptopropyl-N,N′-dimethylethylenediamine, H₂(bmmp-dmed), have been investigated. Reactions with iodomethane yield [(Me-bmmp-dmed)Ni]PF₆ (3), [(Me₂-bmmp-dmed)NiI₂] (4), and [(Me₂-bmmp-dmed)ZnI]₂[ZnI₄] (5). Addition of iodoacetamide yields [(AA₂-bmmp-dmed)Ni]I₂ (6) and [(AA₂-bmmp-dmed)Zn]I₂ (7). Each of the metal-thioether products (3-7) have been characterized spectroscopically and by X-ray crystallography. Structural data is compared with that of the previously reported thiolato precursors 1 and 2. Sulfur-alkylation of 1 results in small relative changes in the nickel-sulfur bond distance, whereas for 2, the zinc-sulfur bond distance increases significantly, but is not cleaved. The difference between nickel and zinc is attributed to the release of a π*-bonding interaction between the metal and sulfur upon alkylation that compensates for the decreased σ-donor ability of the thioether in the case of nickel, but not for zinc.     

Neighbouring metal induced oxidative addition at the iron centre amongst the iron-arylpyridylphosphine complexes

Complexes of the type (η⁴-BuC₅H₅)Fe(CO)₂(P) (P = PPh₂Py 3, PPhPy₂4, PPy₃5; Py = 2-pyridyl) were satisfactorily prepared. Upon treatment of 3 with M(CO)₃(EtCN)₃ (M = Mo, 6a; W, 6b), the pyridyl N-atom could be coordinated to the metal M, which then eliminates a CO ligand from the Fe-centre and induced an oxidative addition of the endo-C-H of (η⁴-BuC₅H₅). This results in a bridged hydrido heterodimetallic complex [(η⁵-BuC₅H₄)Fe(CO)(μ-P,N-PPh₂Py)(μ-H)M(CO)₄] (M = Mo, 7a, 81%; W, 7b, 76%). The reaction of 4 or 5 with 6a,b did not give the induced oxidative addition, although these complexes contain more than one pyridyl N-atom. The reaction of 4 with M(CO)₄(EtCN)₂ (M = Mo, 9a; W, 9b) produced heterodimetallic complexes [(η⁴-BuC₅H₅)Fe(CO)₂(μ-P:N,N′-PPhPy₂)M(CO)₄] (M = Mo, 10a, 81%; W, 10b, 83%). Treatment of 5 with 6a,b gave [(η⁴-BuC₅H₅)Fe(CO)₂(μ-P:N,N′,N″-PPy₃)M(CO)₃] (M = Mo, 12a, 96%; W, 12b, 78%).     

Macropolyhedral boron-containing cluster chemistry: two-electron variations in intercluster bonding intimacy. Contrasting structures of 19-vertex [(η-C5Me5)HIrB18H19(PHPh2)] and [(η-C5Me5)IrB18H18(PH2Ph)]

Fused double-cluster [(η⁵-C₅Me₅)IrB₁₈H₁₈(PH₂Ph)] (8), from syn-[(η⁵-C₅Me₅)IrB₁₈H₂₀] (1) and PH₂Ph, retains the three-atoms-in-common cluster fusion intimacy of 1, in contrast to [(η⁵-C₅Me₅)HIrB₁₈H₁₉(PHPh₂)] (6), from PHPh₂ with 1, which exhibits an opening to a two atoms-in-common cluster fusion intimacy. Compound 8 forms via spontaneous dihydrogen loss from its precursor [(η⁵-C₅Me₅)HIrB₁₈H₁₉(PH₂Ph)] (7), which has two-atoms-in-common cluster-fusion intimacy and is structurally analogous to 6.     

Photoirradiation reactions and crystal structures of two geometrical isomers of [Ru(OAc)(2cqn)2NO] (H2cqn=2-chloro-8-quinolinol)

The photoirradiation reactions of two geometrical isomers (cis-1 and cis-2) of [Ru(OAc)(2cqn)₂NO] (H2cqn=2-chloro-8-quinolinol) were studied. Cis-2 [Ru(OAc)(2cqn)₂NO] (2) photochemically isomerized to cis-1 [Ru(OAc)(2cqn)₂NO] (1) in CH₂Cl₂ or DMSO using an Xe lamp as a light source and the reaction was irreversible. The 2 to 1 isomerization coexisting with ¹⁵NO gas and its evolution of the ¹H NMR spectra showed that the dissociation and recombination of both the NO and the acetate ion involve in the isomerization. On the other hand, 1 did not isomerize but the NO ligand exchanged with ¹⁵NO. The crystal structures of 1 and 2 were determined by X-ray diffraction.     

Dinitrosyl iron complexes [E5Fe(NO)2] (E = S, Se): A precursor of Roussin’s black salt [Fe4E3(NO)7]

[PPN][Se₅Fe(NO)₂] (1) and [K-18-crown-6-ether][S₅Fe(NO)₂] (2′) were synthesized and characterized by IR, UV-Vis, EPR spectroscopy, magnetic susceptibility, and X-ray structure. [PPN][Se₅Fe(NO)₂] easily undergoes ligand exchange with S₈ and (RS)₂ (R = C₇H₄SN (5), o-C₆H₄NHCOCH₃ (6), C₄H₃S (7)) to form [PPN][S₅Fe(NO)₂] and [PPN][(SR)₂Fe(NO)₂]. The reaction displays that [E₅Fe(NO)₂]⁻ (E = Se (3), S (4)) facilely converts to [Fe₄E₃(NO)₇]⁻ by adding acid HBF₄ or oxidant [Cp₂Fe][BF₄] in THF, respectively. Obviously, complexes 1 and 2′ serve as the precursors of the Roussin’s black salts 3 and 4. The electronic structure of {Fe(NO)₂}⁹ core of [Se₅Fe(NO)₂]⁻ is best described as a dynamic resonance hybrid of {Fe⁺¹(NO)₂}⁹ and {Fe⁻¹(NO⁺)₂}⁹ modulated by the coordinated ligands. The findings, EPR signal of g = 2.064 for 1 at 298 K, implicate that the low-molecular-weight DNICs and protein-bound DNICs may not exist with selenocysteine residues of proteins as ligands, since the existence of protein-bound DNICs and low-molecular-weight DNICs in vitro has been characterized with a characteristic EPR signal at g = 2.03. In addition, complex 2′ treated human erythroleukemia K562 cancer cells exposed to UV-A light greatly decreased the percentage survival of the cell cultures.     

Synthesis and characterization of tetrairon-tungsten cluster complex containing a μ4, η-carbonyl ligand

Reaction of [(PPh₂C₅H₄)Cp₃Fe₄(CO)₄] (1) with (CO)₄W(CH₃CN)₂ at ambient temperature affords [(CO)₄W(PPh₂C₅H₄)Cp₃Fe₄(CO)₄] (2) as the major product, together with a small amount of [(CO)₅W(PPh₂C₅H₄)Cp₃Fe₄(CO)₄] (3). Compound 3 can be obtained in good yield by treating (CO)₅W(CH₃CN) with equal molar of 1, and reaction of 3 with Me₃NO in acetonitrile solvent produces 2 exclusively. The crystal structures of 2 and 3 have been determined by an X-ray diffraction study. Compound 2 contains an interesting μ₄, η²-CO ligand, where two electrons donated by the carbon atom are involved to bridge a Fe₃ face and two electrons from oxygen are donated to the tungsten(0) atom.     

fac-/mer-[RuCl3(NO)(P-N)] (P-N = [o-(N,N-dimethylamino)phenyl]diphenylphosphine): Synthesis, characterization and DFT calculations

Complex fac-[RuCl₃(NO)(P-N)] (1) was synthesized from the reaction of [RuCl₃(H₂O)₂(NO)] and the P-N ligand, o-[(N,N-dimethylamino)phenyl]diphenylphosphine) in refluxing methanol solution, while complex mer,trans-[RuCl₃(NO)(P-N)] (2) was obtained by photochemical isomerization of (1) in dichloromethane solution. The third possible isomer mer,cis-[RuCl₃(NO)(P-N)] (3) was never observed in direct synthesis as well as in photo- or thermal-isomerization reactions. When refluxing a methanol solution of complex (2) a thermally induced isomerization occurs and complex (1) is regenerated.The complexes were characterized by NMR (³¹P{¹H}, ¹⁵N{¹H} and ¹H), cyclic voltammetry, FTIR, UV-Vis, elemental analysis and X-ray diffraction structure determination. The ³¹P{¹H} NMR revealed the presence of singlet at 35.6 for (1) and 28.3 ppm for (2). The ¹H NMR spectrum for (1) presented two singlets for the methyl hydrogens at 3.81 and 3.13 ppm, while for (2) was observed only one singlet at 3.29 ppm. FTIR Ru-NO stretching in KBr pellets or CH₂Cl₂ solution presented 1866 and 1872 cm⁻¹ for (1) and 1841 and 1860 cm⁻¹ for (2). Electrochemical analysis revealed a irreversible reduction attributed to Ru^II-NO⁺ → Ru^II-NO⁰ at −0.81 V and −0.62 V, for (1) and (2), respectively; the process Ru^II → Ru^III, as expected, is only observed around 2.0 V, for both complexes.Studies were conducted using ¹⁵NO and both complexes were isolated with ¹⁵N-enriched NO. Upon irradiation, the complex fac-[RuCl₃(NO)(P-N)] (1) does not exchange ¹⁴NO by ¹⁵NO, while complex mer,trans-[RuCl₃(NO)(P-N)] (2) does. Complex mer,trans-[RuCl₃(¹⁵NO)(P-N)] (2′) was obtained by direct reaction of mer,trans-[RuCl₃(NO)(P-N)] (2) with ¹⁵NO and the complex fac-[RuCl₃(¹⁵NO)(P-N)] (1′) was obtained by thermal-isomerization of mer,trans-[RuCl₃(¹⁵NO)(P-N)] (2′).DFT calculation on isomer energies, electronic spectra and electronic configuration were done. For complex (1) the HOMO orbital is essentially Ru (46.6%) and Cl (42.5%), for (2) Ru (57.4%) and Cl (39.0%) while LUMO orbital for (1) is based on NO (52.9%) and is less extent on Ru (38.4%), for (2) NO (58.2%) and Ru (31.5%).     

S-nitrosothiol and nitric oxide reactivity at β-diketiminato zinc thiolates

The β-diketiminato zinc halide [Me₂NN]ZnCl₂Li(THF)₃ (1) is prepared in 51% isolated yield by addition of the lithium β-diketiminate Li[Me₂NN] to ZnCl₂ in THF. Reaction of 1 with 2 equiv. of the thallium thiolate TlSCy provides {[Me₂NN]Zn(μ-SCy)₂Tl}₂ (2), a TlSCy adduct of [Me₂NN]ZnSCy, as colorless crystals in 51% yield. Reaction of 1 with 1 equiv. TlSR provides the dinuclear {[Me₂NN]Zn(μ-SR)}₂ (R = Cy (3), ^tBu (4)) which possess unsymmetrically bridging thiolate ligands with pairs of dissimilar Zn-S distances in the solid state (2.350(3) and 2.417(3) Å for 3; 2.312(1) and 2.415(1) Å for 4). Reaction of 1 with LiSCPh₃ results in the mononuclear zinc thiolates [Me₂NN]ZnSCPh₃(THF) (5) and [Me₂NN]ZnSCPh₃ (6) with shorter, but similar Zn-SR distances of 2.225(2) and 2.214(1) Å. Variable temperature ¹H NMR studies of 3 and 4 in CDCl₃ suggest that the aliphatic thiolates exist predominately as monomeric species in solution near room temperature, though at −50 °C two different β-diketiminato species are observed for 3. Thiolate exchange among 3, 4, and 6 also takes place on the NMR timescale near room temperature. Both 4 and 6 undergo transnitrosylation with CySNO in CDCl₃ to give {[Me₂NN]ZnSCy}₂ (3) and the corresponding S-nitrosothiol ^tBuSNO or Ph₃CSNO. Nitric oxide does not react with 4 or 6 under anaerobic conditions, but in the presence of O₂, NO cleaves the zinc-thiolate bond of 4 to rapidly give ^tBuSNO. Similarly, anaerobic NO₂ reacts with 4 to give ^tBuSNO providing insight into the active nitrogen oxide species capable of cleaving Zn-SR bonds.     

Coordination compounds of Cd(II) with several bidentate-NN′ and tridentate-NN′N nitrogen donor ligands. Cd NMR studies of monomeric compounds containing nitrogen donor atoms

Reaction of CdCl₂ with N-alkylaminopyrazole ligands 1-[(2-ethylamino)ethyl]-3,5-dimethylpyrazole (deae), 1-[(2-(tert-butylamino)ethyl)]-3,5-dimethylpyrazole (deat), bis-[(3,5-dimethylpyrazolyl)methyl]ethylamine (bdmae), and bis-[(3,5-dimethylpyrazolyl)ethyl]ethylamine (ddae) in absolute ethanol yields [CdCl₂(NN′)] (NN′ = deae (1), deat (2)), [CdCl₂(bdmae)] (3), and [CdCl(ddae)]₂[CdCl₄] (4). The Cd(II) complexes have been characterised by elemental analyses, conductivity measurements, IR, ¹H, ¹³C{¹H} and ¹¹³Cd NMR spectroscopies, and X-ray diffraction methods. ¹H and ¹¹³Cd NMR experiments at variable temperature for 3 and 4 show that dynamic processes are taking place in solution. We report the measurements of ¹¹³Cd NMR chemical shift data for complexes 1-4 in solution. X-ray crystal structures for complexes 2 and 3 have been determined. The Cd(II) is coordinated to the deat ligand, in 2, by one nitrogen atom of the pyrazolyl group and one nitrogen atom of the amine. It finishes a tetrahedral geometry with two chlorine atoms. The bdmae ligand is linked to Cd(II), in 3, by two nitrogens atoms of the pyrazolyl groups and one amine nitrogen, along with two chlorine atoms, in a distorted trigonal bipyramidal geometry.     

Relating catalytic activity and electrochemical properties: The case of arene-ruthenium phenanthroline complexes catalytically active in transfer hydrogenation

The electrochemical properties of cationic complexes [(η⁶-arene)Ru(N ∩ N)Cl]Cl (arene/N ∩ N = C₆H₆/1,10-phenanthroline (1), p-MeC₆H₄Prⁱ/1,10-phenanthroline (2), C₆Me₆/1,10-phenanthroline (3), C₆Me₆/5-NO₂-1,10-phenanthroline (4), and C₆Me₆/5-NH₂-1,10-phenanthroline (5)) were studied by cyclic voltammetry in order to rationalize catalytic activity in transfer hydrogenation of the respective aqua complexes [(η⁶-arene)Ru(N ∩ N)(OH₂)](BF₄)₂ (6-10). Complexes 1-5 were chosen because the ‘true’ catalysts 6-10 are unstable under the conditions of the measurement. The electrochemical behaviour of 1-5 in acetonitrile solution is rather complicated due to consecutive and parallel chemical reactions that accompany electron transfer processes. Nonetheless, interpretation of the electrochemical data allowed to assess the influence of the structure and substitution on the redox and catalytic properties: the catalytic ability correlates with the reduction potentials, indicating the decisive role of the η⁶-arene ring directly bonded to the catalytic centre (Ru).     

ansa-Chromocenes: An alternative route to Me2Si(C5Me4)2Cr

The mechanism for the preparation of Me₂Si(C₅Me₄)₂Cr, 1, from CrCl₂(THF)_x and Me₂Si(C₅Me₄)₂Li₂ was investigated and - in contrast to earlier claims - no evidence was found for the participation of an auxiliary ligand. The formation and stability of 1 is attributed to the combination of correct reaction conditions and a highly substituted ligand framework. Reactions with other ligands under identical conditions did not lead to the formation of ansa-chromocenes. Reaction with H₄C₂Ind₂Li₂ afforded the η³-Ind bridged dimer {H₄C₂(η⁵-Ind)(μ-,η³-Ind)Cr}₂, 9. Complex 1 does not coordinate PPh₃ or carbenes, but from reaction with two equivalents of xylyl isocyanide the CH-activated complex Me₂Si(C₅Me₄)(η³-C₅Me₃(H)(CH₂)Cr(CNC₆MeH₃)₂, 7, was obtained. Complexes 7 and 9 were characterised by X-ray crystallography.