Spectrophotometric Determination of Ruthenium with 2-Amino-3-Hydroxypyridine

Ruthenium(III) complexation with 2-amino-3-hydroxpyridine is studied spectrophotometrically. The violet-red complex (λ_max 520 nm; ? 4460) contains metal and the ligand in 1 : 1 molar ratio, adheres to Beer's law from 0 to 16.5 µg/ml of ruthenium concentration and shows maximum and constancy in absorbance between pH 5.3 and 6.5. The complexation is used in the spectro-photometric determination of ruthenium in coexistence with several ions including some from platinum metals.     

Ruthenium Catalyzed Reactions of Aldehydes: Molecular Structures of Ruthenium Complexes with Aldehyde Ligands

[RuCl(H)(CO)(PPh₃)₃] (2) was found to catalyze, in the presence of H₂C=CHSiMe₃ (3), the trimerisation of aldehydes RCHO [R=Et (4a), i-Bu (4b)] yielding 1,3,5-trioxanes (5) and the aldol condensation yielding α,β-unsaturated aldehydes (6). When (4a) was used as a reactant, from these reaction mixtures, the ruthenium complex [RuCl₂(CO)(PPh₃)₂(i-BuCHO-κO)] (7) having the aldol condensation product as the ligand crystallized. In the analogous reaction with (4b), the complex [RuCl₂(CO)(PPh₃)₂(i-BuCHO-κO)] (8) with the aldehyde as ligand was obtained. The constitution of these complexes was established by single-crystal X-ray diffraction measurements. The ruthenium centers are octahedrally coordinated having the aldehyde and the carbonyl ligand in mutually trans positions (coordination index: OC-6-12). The aldehydes are monodentately coordinated via the carbonyl oxygen atom (κO). The coordination induced elongations of the C=O double bonds [1.242(4) Å (7), 1.234(4) Å (8)] indicate an activation of the aldehydes. Furthermore, the Ru-CO bond lengths [1.842(4) Å (7), 1.823(4) Å (8)] exhibit a relatively low trans influence of the aldehyde ligands. The formation of the complexes (7) and (8) give an indication that the Lewis acidity of the ruthenium center is of importance for aldehyde activation in the catalytic process.     

Rare Earth Metal Ruthenium Gallides R2Ru3Ga9 with Y2Co3Ga9 Type Structure

The twelve isotypic intermetallic compounds R₂Ru₃Ga₉ with R = Y, La–Nd, Sm, Gd–Tm were prepared by arc‐melting of the elemental components. Their crystal structure was determined from single‐crystal X‐ray data of Dy₂Ru₃Ga₉: Cmcm, a = 1279.3(2) pm, b = 755.6(1) pm, c = 964.7(1) pm, Z = 4, R = 0.020 for 671 structure factors and 42 variable parameters. All atomic positions have within two standard deviations ideal occupancies (occupancy values vary between 98.8(5) and 101.2(6)%). The structure is briefly discussed, emphasizing its relation to other structures with a high content of gallium or aluminum.     

Studies on Ruthenium(III) Chalconate Complexes Containing PPh3/AsPh3

The reactions of [RuX₃(EPh₃)₃] (X = Cl or Br; E = P or As) with 2′-hydroxychalcones in benzene under reflux led to the formation of [RuX₂(EPh₃)₂(L)] (X = Cl or Br; E = P or As; L = chalconates). The new complexes have been characterized by analytical and spectroscopic (IR, electronic, and EPR) data. The redox behavior of the complexes has also been studied. Based on the data, an octahedral structure has been assigned for all the complexes. The new complexes exhibit efficient catalytic activity for the oxidation of primary and secondary alcohols into their corresponding aldehydes and ketones in the presence of N-methylmorpholine-N-oxide (NMO) as co-oxidant and also found efficient catalytic activity for the transfer hydrogenation of ketones. The antifungal properties of the complexes have also been examined and compared with standard Bavistin.

Supplemental materials are available for this article. Go to the publisher's online edition of Phosphorus, Sulfur, and Silicon and the Related Elements to view the free supplemental file.     

Chemistry of Ruthenium Polypyridine Complexes: V. Electronic Structure of Ruthenium(II) Bipyridine-Diphosphine Mixed-Ligand Complexes

Comparative analysis of the donor-acceptor capacities of diphosphine ligands in two series of complexes: cis-[Ru(bpy)2(LL)]^{q +} [LL = 2,2'-bipyridine (bpy), o-benzoquinonediimine (bqdi), cis-1,2-bis(diphenylphosphino)ethane, cis-1,2-bis(diphenylphosphino)ethylene (dppen), (NH3)2, and (CO)2] and [Ru(NH₃)₄. (LL)]^{2 +} (LL = bpy, dppen, and bqdi), was performed. Diphosphines are the strongest donors; they compare in -acceptor capacity which is associated with phosphorus d orbitals with 2,2'-bipyridine and fall far short of o-benzoquinonediimine and carbonyl.     

Synthesis and Study of Ruthenium Phthalocyanine Complexes

Methods of synthesis of ruthenium tetra-tert-butylphthalocyaninate (Pc ^t Ru) were developed. The synthesis performed in both autoclave and in open system (in isoamyl alcohol in the presence (1,8-diazabicyclo[5,4,0]undecene) resulted in Pc ^t Ru() containing CO as axial ligand. When quinoline was used in the synthesis of Pc ^t Ru, the Pc ^t Ru(Iqnl)₂ complex was obtained with two isoquinoline molecules (Iqnl) as axial ligands, which were detached consecutively in the course of thermogravimetric analysis. The compounds formed were studied by different physicochemical methods: electron, IR, and ¹H NMR spectroscopies, MALDI-TOF mass spectroscopy, thermogravimetric and elemental analyses.     

Theoretical Study of Hydrogen Adsorption on Ruthenium Clusters

The geometries, stabilities, electronic, and magnetic properties of hydrogen adsorption on Ru _n clusters have been systematically investigated by using density functional theory with generalized gradient approximation. The result indicates the absorbed species does not lead to a rearrangement of the basic cluster. For n > 2, three different adsorption patterns are found for the Ru _n H₂ complexes: One H atom binds to the Ru top site, and another H binds to the bridge site for n = 3, 5, 6, 8; bridge site adsorption for n = 4; hollow site and top site adsorption for n = 7. The adsorption energies display oscillation and reach the peak at n = 2, 4, 7, implying their high chemical reactivity. The small electron transferred number between H atoms and Ru _n clusters indicates that the interaction between H atoms and Ru _n clusters is small. When H₂ is absorbed on the Ru _n clusters, the chemical activity of corresponding clusters is dramatically increased. The absorbed H₂ can lead to an oscillatory behavior of the magnetic moments, and this behavior is rooted in the electronic structure of the preceding cluster and the changes in the magnetic moment are indicative of the relative ordering of the majority and minority LUMO’s. The second order difference indicates 5 is magic number in Ru _n H₂ and Ru _n clusters.     

Structural Diversity and Magnetic Properties of Hybrid Ruthenium Halide Perovskites and Related Compounds

There has been a great deal of recent interest in extended compounds containing Ru³⁺ and Ru⁴⁺ in light of their range of unusual physical properties. Many of these properties are displayed in compounds with the perovskite and related structures. Here we report an array of structurally diverse hybrid ruthenium halide perovskites and related compounds: MA₂RuX₆ (X=Cl or Br), MA₂MRuX₆ (M=Na, K or Ag; X=Cl or Br) and MA₃Ru₂X₉ (X=Br) based upon the use of methylammonium (MA=CH₃NH₃⁺) on the perovskite A site. The compounds MA₂RuX₆ with Ru⁴⁺ crystallize in the trigonal space group and can be described as vacancy‐ordered double‐perovskites. The ordered compounds MA₂MRuX₆ with M⁺ and Ru³⁺ crystallize in a structure related to BaNiO₃ with alternating MX₆ and RuX₆ face‐shared octahedra forming linear chains in the trigonal space group. The compound MA₃Ru₂Br₉ crystallizes in the orthorhombic Cmcm space group and displays pairs of face‐sharing octahedra forming isolated Ru₂Br₉ moieties with very short Ru–Ru contacts of 2.789 Å. The structural details, including the role of hydrogen bonding and dimensionality, as well as the optical and magnetic properties of these compounds are described. The magnetic behavior of all three classes of compounds is influenced by spin–orbit coupling and their temperature‐dependent behavior has been compared with the predictions of the appropriate Kotani models.     

Shine,Shine, Ruthenium Caged Drug†

This is a highlight on the paper by Bonnet et al.: A Lock-and-Kill Anticancer Photoactivated Chemotherapy Agent. which constitutes an important step toward establishing photoactivated chemotherapy (PACT) as a widespread tool to treat different health issues, specially tumors. PACT can be a useful technique to deliver already tested drugs, where the effect of the desired molecule is directed only to its target after light irradiation, even in the cases in which it is difficult to achieve a precise delivery in the desired organ or tissue. Ruthenium-polipyridyl caged-compounds are near ideal devices to deliver a drug in that precise fashion, albeit they usually fail in revealing their actual location due to their weak light emission properties. The mentioned work introduces a simple and clever idea: the use of a covalently linked fluorophore to map the caged-compounds in-vivo distribution prior to the eventual irradiation to activate the chemotherapy.     

Synthesis and Structure of η4-Enone Complexes of Ruthenium(0)

A variety of [Ru(CO)₂L(η⁴enone)] complexes (L = phosphines, phosphites, and arsines, enone = (E)-4-phenylbut-3-en-2-one) have been synthesized. ¹H-, ¹³C-, and ³¹P-NMR spectra are reported and the X-ray structures of two Ru complexes with L ? Ph₃P(7), Et₃P ( 10 ) and one Fe complex with L ? Ph₃P ( 14 ) are presented. All three compounds crystallize in the same monoclinic space group P2₁/n with a = 10.575(2) Å, b =9.213(2) Å, and c = 27.608(5) Å, β = 100.04(2)°, Z = 4 for 7 , a = 10.276(3) Å, b = 12.935(3) Å, and c = 14.854(2) Å, β = 96.96(2)°, Z = 4 for 10 , and a = 10.492(2) Å, b = 9.232(3) Å, and c = 27.129(3) Å, β = 98.67(2)°, Z = 4 for 14 . The structures of the Ru complexes are compared with the Fe analogues. In the case of M ? Ru and L ? (EtO)₃P, (MeO)₃P, and (i-PrO)₃P ( 9 , 11 , and 13 , respectively) stereoisomers could be detected by ³¹P-NMR at room temperature, wich arise from rotation at the coordinated metal centre.     

Ruthenium(II) Complexes with Three Different Diimine Ligands

The synthesis of tri-heteroleptic complex of Ru(II) with diimine ligands is describe. Ten compounds [Ru(R₂bpy) (biq) (L)][PF₆]₂ (R = H, CH₃); L = 2,2′-bipyridine (bpy), 4,4′-dimethyl-2,2′-bipyridine (Me₂bpy), 2,2′-bipyrimidine (bpm), 2,2′-biisoquinoline (biiq), 1,10-phenanthroline (phen), dipyrido[3,2-c:2′,3′-e]pyridazine (taphen), 2,2′-biquinoline (biq), 6,7-dihydrodipyrido[2,3-b:3,2-j][1,10]-phenanthroline (dinapy), 2-(2[pyridyl)quinoline (pq), 1-(2-pyrimidyl)pyrazole] (pzpm), 2,2′-biimidazole (H₂biim) are characterized by elemental analysis, electronic and ¹H-NMR spectroscopy. The relative photosustitution rates of biq in MeCN are given at three temperatures.     

Ruthenium catalysts of liquid-phase hydrocracking ofn-alkanes

Catalysts of liquid-phase hydrocracking ofn-alkanes with higher activity than Ru-black were obtained by decomposition of Ru₃(CO)₁₂ and Ru₃(CO)₁₂ +i-Bu₂AlH in alkanes at 180–200°C and 5 MPa H₂ and (benzene)(1,3-cyclohexadiene)ruthenium at 20°C and 0.1 MPa H₂. The system based on Ru₃(CO)₁₂ +i-Bu₂AlH is x-ray amorphous, and the remainder have a 30–60 Å particle size.A. N. Nesmeyanov Institute of Organoelemental Compounds, Russian Academy of Sciences, 117813 Moscow. Translated from Izvestiya Akademii Nauk, Seriya Khimicheskaya, No. 5, pp. 1211–1213, May, 1992.     

Ruthenium(III) chalconate complexes containing PPh3/AsPh3 and their use as catalysts

Ruthenium(III) complexes of the type [RuX(EPh₃)(L)₂] (X?=?Cl or Br; E?=?P or As; L?=?2-hydroxychalcone) have been prepared by reacting [RuX₃(EPh₃)₃] with 2-hydroxychalcones in benzene under reflux. The new complexes have been characterized by analytical and spectroscopic (infrared, electronic, electron paramagnetic resonance, and mass) methods. Redox potential studies of the complexes have been carried out to elucidate the electronic structure, geometry, and electrochemical features. On the basis of data obtained, an octahedral structure has been assigned for all the complexes. The new complexes exhibit catalytic activity for the oxidation of primary and secondary alcohols into their corresponding aldehydes and ketones in the presence of N-methylmorpholine-N-oxide as co-oxidant and they were also found to be efficient catalyst for the transfer hydrogenation of ketones.     

Ruthenium complexes containing aromatic thioamides

Summary Reaction of aromatic thioamides, LH, withcis-[Ru(CO)₂Cl₂] yieldscis-[Ru(CO₂)Cl₂LH]. The complexes have been characterised by analytical, i.r., electronic and n.m.r. spectral and magnetic measurements. All the Ru^II diamagnetic complexes have been assigned distorted octahedral geometry.     

Strained Ruthenium Complexes Bearing Tridentate Guanidine-Derived Ligands

The dimer [{(η⁶-p-cymene)RuCl}₂(μ-Cl)₂] (cymene=MeC₆H₄ⁱPr) reacts with N,N′-bis(p-tolyl)-N′′-(2-pyridinylmethyl)guanidine ( H₂L1 ) and N,N′-bis(p-tolyl)-N′′-(2-diphenylphosphanoethyl)guanidine ( H₂L2 ), in the presence of NaSbF₆, giving rise to chlorido compounds of formula [(η⁶-p-cymene)RuCl( H₂L )][SbF₆] ( H₂L = H₂L1 ( 1 ), H₂L2 ( 2 )) in which the guanidine ligand adopts a κ² chelate coordination mode. The related ligand (S)-N,N′-bis(p-tolyl)-N′′-(1-isopropyl, 2-diphenylphosphano ethyl)guanidine ( H₂L3 ) affords mixtures of the corresponding chlorido compound [(η⁶-p-cymene)RuCl( H₂L3 )][SbF₆] ( 3 ) together with the complexes [(η⁶-p-cymene)RuCl₂( H₃L3 )][SbF₆] ( 4 ) and [(η⁶-p-cymene)Ru(κ³N,N′,P- HL3 )][SbF₆] ( 10 ) which contain phosphano-guanidinium and phosphano-guanidinate ions acting as monodentate and tridentate ligand, respectively. Compounds 1 , 2 and mixture of 3 / 4 / 10 react with AgSbF₆ rendering the cationic aqua-complexes [(η⁶-p-cymene)Ru( H₂L )(OH₂)][SbF₆]₂ ( H₂L = H₂L1 ( 5 ), H₂L2 ( 6 ), H₂L3 ( 7 )). These aqua-complexes exhibit a temperature-dependent fluxional process in solution. Experimental NMR studies and DFT theoretical calculations on complex 6 suggest that the process involves the exchange between two rotamers around one of the C−N guanidine bonds. Treatment of 5 – 7 with NaHCO₃ renders the complexes [(η⁶-p-cymene)Ru(κ³N,N′,N′′- HL1 )][SbF₆] ( 8 ) and [(η⁶-p-cymene)Ru(κ³N,N′,P- HL )][SbF₆] ( HL = HL2 ( 9 ), HL3 ( 10 )), respectively, in which the HL ligand adopts a fac κ³ coordination mode. The new complexes have been characterized by analytical and spectroscopic means, including the determination of the crystal structures of the compounds 1 , 2 , 5 , 9 and 10 , by X-ray diffractometric methods.     

Alkene Isomerisation Catalysed by a Ruthenium PNN Pincer Complex

The [Ru(CO)H(PNN)] pincer complex based on a dearomatised PNN ligand (PNN: 2‐di‐tert‐butylphosphinomethyl‐6‐diethylaminomethylpyridine) was examined for its ability to isomerise alkenes. The isomerisation reaction proceeded under mild conditions after activation of the complex with alcohols. Variable‐temperature (VT) NMR experiments to investigate the role of the alcohol in the mechanism lend credence to the hypothesis that the first step involves the formation of a rearomatised alkoxide complex. In this complex, the hemilabile diethylamino side‐arm can dissociate, allowing alkene binding cis to the hydride, enabling insertion of the alkene into the metal–hydride bond, whereas in the parent complex only trans binding is possible. During this study, a new uncommon Ru⁰ coordination complex was also characterised. The scope of the alkene isomerisation reaction was examined.     

Ruthenium Tris-pyrazolylborate Complexes XVII [1]. Structure and Bonding in a Series of Ruthenium Hydrido-tris-(pyrazolyl)-borate Cyclooctadiene Complexes

Summary.  The complexes RuTp(cod)X (X = Br⁻ (2), I⁻ (3), CN⁻ (4)) have been obtained by the reaction of RuTp(cod)Cl (1) with KX in boiling MeOH in high yields. The cationic complexes [RuTp(cod)(py)]⁺ (5), [RuTp(cod)(dmso)]⁺ (6), and [RuTp(cod)(CH₃CN)]⁺ (7) were prepared as the CF₃SO₃ ⁻ salts by reacting 1 with 1 equivalent of AgCF₃SO₃ in the presence of the respective co-ligand in CH₂Cl₂. The crystal structures of 1, 3, 4, 5, 6, and 7 are reported. Structural features are discussed in conjunction with ¹H, ¹³C, and ¹⁵N NMR spectroscopic data revealing a linear correlation of ¹⁵N chemical shifts and Ru-N (trans to X(L)) bond distances. Received August 31, 2000. Accepted (revised) October 23, 2000     

Theoretical Modelling of Photoswitching of Hyperpolarisabilities in Ruthenium Complexes

Static excited‐state polarisabilities and hyperpolarisabilities of three Ru^II ammine complexes are computed at the density functional theory (DFT) and several correlated ab initio levels. Most accurate modelling of the low energy electronic absorption spectrum is obtained with the hybrid functionals B3LYP, B3P86 or M06 for the complex [Ru^II(NH₃)₅(MeQ⁺)]³⁺ (MeQ⁺=N‐methyl‐4,4′‐bipyridinium, 3 ) in acetonitrile. The match with experimental data is less good for [Ru^II(NH₃)₅L]³⁺ (L=N‐methylpyrazinium, 2 ; N‐methyl‐4‐{E,E‐4‐(4‐pyridyl)buta‐1,3‐dienyl}pyridinium, 4 ). These calculations confirm that the first dipole‐ allowed excited state (FDAES) has metal‐to‐ligand charge‐transfer (MLCT) character. Both the solution and gas‐phase results obtained for 3 by using B3LYP, B3P86 or M06 are very similar to those from restricted active‐space SCF second‐order perturbation theory (RASPT2) with a very large basis set and large active space. However, the time‐dependent DFT λ_max predictions from the long‐range corrected functionals CAM‐B3LYP, LC‐ωPBE and wB97XB and also the fully ab initio resolution of identity approximate coupled‐cluster method (gas‐phase only) are less accurate for all three complexes. The ground state (GS) two‐state approximation first hyperpolarisability β_2SA for 3 from RASPT2 is very close to that derived experimentally via hyper‐Rayleigh scattering, whereas the corresponding DFT‐based values are considerably larger. The β responses calculated by using B3LYP, B3P86 or M06 increase markedly as the π‐conjugation extends on moving along the series 2 → 4 , for both the GS and FDAES species. All three functionals predict substantial FDAES β enhancements for each complex, increasing with the π‐conjugation, up to about sevenfold for 4 . Also, the computed second hyperpolarisabilities γ generally increase in the FDAES, but the results vary between the different functionals.     

Preparation and Crystal Structures of Ruthenium and Osmium Oxide Tetrahalides

RuOF₄ as the highest valence oxide fluoride exist as a molecular compound (a = 606.0(1), b = 836.1(1), c = 626.3(1) pm, β = 91.637(3), Z = 4; P2₁/n) as well as fluorine bridged polymer (a = 547.7(2), b = 928.5(3), c = 1252.4(3) pm, Z = 8, P2₁2₁2₁). A reproducible method for pure, deep blue OsOF₄ is given. Pure OsOF₄‐I is isostructural to the fluorine bridged polymeric RuOF₄ (a = 554.6(1), b = 955.4(2), c = 1278.4(2), Z = 8, P2₁2₁2₁). OsOF₄‐II is also a fluorine bridged polymer (a = 537.8(2), b = 1274.8(4), c = 555.2(2), β = 117.716(6)°, Z = 4, P2₁/c). OsOCl₄ again is a molecular species (a = 938.9(2), b = 561.3(1), c = 1192.0(2), β = 109.944(4)°, Z = 4, P2₁/c).