Structural Variety of Niobium(V) Polyoxo Clusters Obtained from the Reaction with Aromatic Monocarboxylic Acids: Isolation of {Nb2O}, {Nb4O4} and {Nb8O12} Cores

The reactivity of aryl monocarboxylic acids (benzoic, 1- or 2-naphtoic, 4’-methylbiphenyl-4-carboxylic, and anthracene-9-carboxylic acids) as complexing agents for the ethoxide niobium(V) (Nb(OEt)₅ precursor has been investigated. A total of eight coordination complexes were isolated with distinct niobium(V) nuclearities as well as carboxylate complexation states. The use of benzoic acid gives a tetranuclear core Nb₄(μ₂-O)₄(L)₄(OEt)₈] (L=benzoate ( 1 )) with four Nb−(μ₂-O)−Nb linkages in a square plane configuration. A similar tetramer, 7 , was obtained with 2-naphtoic acid by using a 55 % humid atmosphere synthetic route. Two types of dinuclear brick were identified with one central Nb−(μ₂-O)−Nb linkage; they differ in their complexation state, with one bridging carboxylate ([Nb₂(μ₂-O)(μ₂-OEt)(L)(OEt)₆], with L=1-naphtoate ( 3 ) or anthracene-9-carboxylate ( 5 )) or two bridging carboxylate groups ([Nb₂(μ₂-O)(L)₂(OEt)₆], with L=4’-methylbiphenyl-4-carboxylic ( 4 ) or anthracene-9-carboxylate ( 6 )). An octanuclear moiety [Nb₈(μ₂-O)₁₂(L)₈(η₁-L)_4−x(OEt)_4+x] (with L=2-naphtoate, x=0 or 2; 8 ) was obtained by using a solvothermal route in acetonitrile; it has a cubic configuration with niobium centers at each node, linked by 12 μ₂-O groups. The formation of the niobium oxo clusters was characterized by infrared and liquid ¹H NMR spectroscopy in order to analyze the esterification reaction, which induces the release of water molecules that further react through oxolation with niobium atoms, in different {Nb₂O}, {Nb₄O₄} and {Nb₈O₁₂} nuclearities.     

Isolation and single crystal study of [Nb2(μ-OMe)2(OiPr)8]. Can alcohol interchange provide the homoleptic niobium isopropoxide?

Niobium isopropoxide, Nb(OⁱPr)₅, is an attractive precursor of simple and complex niobium oxides in sol-gel technology. This compound cannot, unfortunately, be obtained by alcohol interchange starting from linear chain homologues such as Nb(OMe)₅ or Nb(OEt)₅. The equilibrium in the latter reaction favours formation of mixed-ligand complexes, [Nb₂(OR)₂(OⁱPr)₈], R = Me, Et. In particular, [Nb₂(OMe)₂(OPrⁱ)₈] (1) has been isolated in high yield from repeated treatment of Nb₂(OMe)₁₀ with excess of isopropanol. The X-ray single crystal study reveals a dinuclear structure containing a pair of edge-sharing octahedra with methoxide ligands in the bridging position. Infrared (IR) and mass spectroscopy (MS) studies confirmed the incomplete ligand substitution. The ¹H-NMR spectra suggest equilibrium between different molecular forms in solution. Solvothermal interaction of 1 with La chips in toluene/isopropanol media results in formation of a mixture of LaNb₂(OⁱPr)₁₃ and La₂Nb₄(μ₄−O)₄(OH)₂(μ−OⁱPr)₈(OⁱPr)₈ (2). Electronic Supplementary Material The online version of this article (doi: ) contains supplementary material, which is available to authorised users.     

Structural characterization of dinuclear Ti(IV) complexes of rigid tetradentate dianionic diamine bis(phenolato) ligands; effect of steric bulk on coordination features

A small difference in diamine bis(phenolato) ligands, namely an additional single methylene unit, directs formation of dinuclear Ti(IV) complexes rather than mononuclear ones as characterized by X-ray crystallography. Varying steric bulk of the ligand affects the coordination number in the dinuclear complexes and the ligand to metal ratio. A ligand with reduced steric bulk leads to a L₂Ti₂(OiPr)₄ type complex featuring two octahedral metal centers bridged only by the two phenolato ligands, whereas a bulky ligand leads to a Ti₂(μ-L¹)(μ-OiPr)₂(OiPr)₄ type complex with a single chelating ligand, two bridging isopropoxo ligands, and two terminal isopropoxo groups on each of the two metal centers, which are of trigonal bi-pyramidal geometry.     

Intrinsic Molybdenum-Based POMOFs with Impressive Gas Adsorptions and Photochromism

Novel molybdenum(VI/V) POM-based self-constructed frameworks [Mo^VI₁₂O₂₄(μ₂-O)₁₂(trz)₆(H₂O)₆] ⋅ 6Hma ⋅ 18H₂O ( 1 , Htrz=1H-1,2,3-triazole, ma=methylamine), [Mo^VI₇O₁₄(μ₂-O)₈(trz)₅(H₂O)] ⋅ 7Hma ⋅ 5H₂O ( 2 ), Na₃[Mo^V₆O₆(μ₂-O)₉(Htrz)₃(trz)₃] ⋅ 7.5H₂O ( 3 ) and [Mo^V₈O₈(μ₂-O)₁₂(Htrz)₈] ⋅ 30H₂O ( 4 ) have been covalently decorated with tri-coordinated deprotonated/protonated 1,2,3-triazoles. Channels with an inner diameter of 7.5 Å were found in 1 , whereas a tunnel composed of stacking molecules with an inner diameter of 4.1 Å along the b-axis exists in 2 ; it is occupied by free disordered methylamines, showing selective adsorption of O₂ and CO₂ at 25 °C. Obvious downfield shifts were observed by ¹³C NMR spectroscopies for methylamines inside the confined channels in 1 and 2 . There are diversified pores in 3 and 4 , which are formed by the molecules themselves and intermolecular accumulations. Adsorption tests indicate that 3 and 4 are fine adsorption materials for CH₄ and CO₂ under low pressure that rely on the environments built by the POMs. Correspondingly, 1 and 2 display reversible photoresponsive thermochromism that is subtlety influenced by the channels. The polyoxometalate organic frameworks (POMOFs) with multiple functional adsorptions are easy to assemble. Their photo-/thermoresponse properties offer a new pathway for the self-constructions of one-off hybrid materials that possess the good properties of both POMs and MOFs.     

Cobalt(II) Complexes with N‐Thioacylamidophosphates and 2,2′‐Bipyridyl and 1,10‐Phenathroline. Crystal Structures,Solution 1H NMR Spectral and Magnetic Properties

Structure and magnetic properties of N‐diisopropoxyphosphorylthiobenzamide PhC(S)‐N(H)‐P(O)(OiPr)₂ ( HL^I ) and N‐diisopropoxyphosphoryl‐N′‐phenylthiocarbamide PhN(H)‐C(S)‐N(H)‐P(O)(OiPr)₂ ( HL^II ) complexes with the Co^II cation of formulas [Co{PhC(S)‐N‐P(O)(OiPr)₂}₂] ( 1 ), [Co{PhN(H)‐C(S)‐N‐P(O)(OiPr)₂}₂] ( 2 ), [Co{PhC(S)‐N(H)‐P(O)(OiPr)₂}₂{PhC(S)‐N‐P(O)(OiPr)₂}₂] ( 1a ) and [Co{PhC(S)‐N‐P(O)(OiPr)₂}₂}(2,2′‐bipy)] ( 3 ), [Co{PhC(S)‐N‐P(O)(OiPr)₂}₂(1,10‐phen)] ( 4 ), [Co{PhN(H)‐C(S)‐N‐P(O)(OiPr)₂}₂(2,2′‐bipy)] ( 5 ), [Co{PhN(H)‐C(S)‐N‐P(O)(OiPr)₂}₂(1,10‐phen)] ( 6 ) were investigated. Paramagnetic shifts in the ¹H NMR spectrum were observed for high‐spin Co^II complexes with HL^I,II , incorporating the S‐C‐N‐P‐O chelate moiety and two aromatic chelate ligands. Investigation of the thermal dependence of the magnetic susceptibility has shown that the extended materials 1‐2 and 6 show ferromagnetic exchange between distorted tetrahedral ( 1 , 2 ) or octahedral ( 1a , 6 ) metal atoms whereas 3 and 5 show antiferromagnetic properties. Compound 4 behaves as a spin‐canted ferromagnet, an antiferromagnetic ordering taking place below a critical temperature, T_c = 115 K. Complexes 1 and 1a were investigated by single crystal X‐ray diffraction. The cobalt(II) atom in complex 1 resides a distorted tetrahedral O₂S₂ environment formed by the C=S sulfur atoms and the P=O oxygen atoms of two deprotonated ligands. Complex 1a has a tetragonal‐bipyramidal structure, Co(O^ax)₂(O^eq)₂(S^eq)₂, and two neutral ligand molecules are coordinated in the axial positions through the oxygen atoms of the P=O groups. The base of the bipyramid is formed by two anionic ligands in the typical 1,5‐O,S coordination mode. The ligands are in a trans configuration.     

Synthesis,Crystal Structures,and Thermolysis Studies of Heteronuclear Transition Metal Aluminum Alcoholates

Heteronuclear alcoholate complexes [M{Al(OiPr)₄}₂(bipy)] ( 2-M , M = Fe, Co, Ni, Cu, Zn) and [M{Al(OcHex)₄}₂(bipy)] ( 3-M , M = Fe, Co, Ni, Zn) are formed by adduct formation of [M{Al(OiPr)₄}₂] ( 1-M , M = Fe, Co, Ni, Cu, Zn) with 2,2'-bipyridine and transesterification reaction with cHexOAc. According to crystal structure analyses, in 2-M and 3-M the central transition metal ion M²⁺ is coordinated by two chelating Al(OR)₄^– moieties and one bipyridine ligand in an octahedral arrangement. Treating 1-Cu with 2,2'-bipyridine leads to a reduction process, whereat the intermediate [Cu{Al(OiPr)₄}(bipy)₂][Al(OiPr)₄] ( 4 ) could be structurally characterized. During conversion of the iso-propanolate ligands in 1-Cu to cyclohexanolate ligands, Cu²⁺ is reduced to Cu⁺ forming [Cu{Al(O^cHex)₄}(py)₂] ( 5 ). UV/Vis-spectra and results of thermolysis studies by TG/DTA-MS are reported.     

Reactions of chlorotitanium tri-iso-propoxide with methanol and tributylamine

Reactions of TiCl(OⁱPr)₃ with methanol or tributylamine in heptane resulted in the formation of crystalline Ti₄Cl₂(μ₃-OMe)₂(μ₂-OMe)₄(OⁱPr)₈ and [Bu₃NH][Ti₂Cl₃(OⁱPr)₆], respectively. The solid state structures of both compounds are described.     

Heterometallic Alkoxides of Molybdenum and Heavy Transition Metals—the Synthesis and Prospects of Application

The alkoxides of molybdenum and other heavy transition elements such as Ta or Nb were found to be unreactive towards each other. The bimetallic derivatives could be obtained either via partial hydrolysis that gave Mo₂Ta₄O₈(OMe)₁₆ (I) or via partial thermolysis that provided access to Mo₄Ta₂O₈(OⁱPr)₁₄ (II), Mo₃Ta₂O₈(OⁱPr)₁₀ (III), Mo₄Ta₄O₁₆(OⁱPr)₁₂ (IV), Mo₄Nb₂O₈(OⁱPr)₁₄ (V) and Mo₄W_2–x Mo _x O₁₀(OⁱPr)₁₂ (VI). I–VI can be isolated only from hydrocarbon media as the presence of alcohols leads to precipitation of insoluble homometallic derivatives of molybdenum. The cathodic reduction of MoO(OR)₄ (R = Me, Et) in the presence of LiCl and M(OR)₅ (M = Nb, Ta) leads only to formation of LiMo₂O₂(OMe)₇(MeOH) (VII) or LiMo₂O₂(OEt)₇ (VIII) respectively.     

Synthesis, crystal structure and electrochemical behavior of tetranuclear transition metal clusters based on lacunary silicotungstates: [M4(H2O)2(SiW9O34)2]10− (M = Ni2+, Co2 +) and [Fe4(μ-O)2(μ-OH)2(SiW10O37)2]14−

Three tetranuclear transition metal clusters based on lacunary silicotungstates [M₄(H₂O)₂(SiW₉O₃₄)₂]^12? (M = Ni²⁺ (1), Co²⁺ (2)), and [Fe₄(μ-O)₂(μ-OH)₂(SiW₁₀O₃₇)₂]^14? (3) have been synthesized under ambient conditions and characterized by elemental analyses, IR, TG, cyclic voltammetry, and single-crystal X-ray diffraction. The polyoxoanions of 1 and 2 are isostructural, including a central rhomb-like {M₄O₁₆} (M = Ni, Co) cluster sandwiched by two trivacant {B-α-SiW₉} Keggin moieties. In the polyoxoanion of 3, two μ-OH and two μ-O bridges link with four Fe^III ions, forming an eight-membered ring. This [Fe₄(μ-OH)₂(μ-O)₂] aggregation is sandwiched by two bi-vacant {α-SiW₁₀} Keggin fragments. The electrochemical properties of the three compounds were investigated.     

Synthesen und Kristallstrukturen neuer chalkogenido‐verbrückter Niob‐Kupfer‐Cluster

Syntheses and Crystal Structures of Novel Chalcogenido‐bridged Niobium Copper Clusters In the presence of tertiary phosphines, the reaction of NbCl₅ and Copper(I) salts with Se(SiMe₃)₂ (E = S, Se) affords the new chalcogenido‐bridged niobium‐copper cluster compounds ( 1 ) and [NbCu₄Se₄Cl (PPh₃)₄] ( 2 ). Using E(R)SiMe₃ (E = S, Se, R = Ph, ⁿPr) instead of the bisilylated selenium species leads to the compounds [NbCu₂(SPh)₆(PMe₃)₂] ( 3 ), [NbCu₂(SPh)₆(PⁿPr₃)₂] ( 4 ), [NbCu₂(SePh)₆(PMe₃)₂] ( 5 ), [NbCu₂(SePh)₆(PⁿPr₃)₂] ( 6 ), [NbCu₂(SePh)₆(PⁱPr₃)₂] ( 7 ), [NbCu₂(SePh)₆(P^tBu₃)₂] ( 8 ), [NbCu₂(SePh)₆(PⁱPr₂Me)₂] ( 9 ), [NbCu₂(SePh)₆(PPhEt₂)₂] ( 10 ), [Nb₂Cu₂(SⁿPr)₈(PⁿPr₃)₂Cl₂] ( 11 ) and [Nb₂Cu₆(SⁿPr)₁₂(PⁱPr₃)₂Cl₄]·2 CH₃CN ( 12 ·2 CH₃CN). By reacting Cu^I salts and NbCl₅ with the monosilylated selenides Se(^tBu)SiMe₃ and Se(ⁱPr)SiMe₃ which have a weak Se–C bond the products [Nb₂Cu₆Se₆(PⁱPr₃)₆Cl₄] ( 13 ), [Nb₂Cu₄Se₂(SeⁱPr)₆(PⁿPr₃)₄Cl₂] ( 14 ) and [Nb₂Cu₆Se₂(SeⁱPr)₁₀(PEt₂Me)₂Cl₂]·DME ( 15 ) are formed which contain selenide as well as alkylselenolate ligands. The molecular structures of all of these new compounds were determined by single crystal X‐ray diffraction measurements.     

Two Titanium-oxo-Clusters with Malonate and Succinate Ligands: Single-Crystal Structures and Catalytic Property

Two alkane dicarboxylates substituted titanium-oxo-clusters, Ti₆O₃(OOCCH₂COO)₂(O ⁱ Pr)₁₄ (1) and Ti₆O₃(OOCC₂H₄COO)₂(O ⁱ Pr)₁₄ (2), were successfully prepared by one step in situ solvothermal synthesis. The compounds are the first examples of only flexible alkane dicarboxylate-substituted titanium-oxo-clusters. The structures of the compounds are best described as two trinuclear oxo-Ti₃ subunits linked by a μ ₂-O bridge and two malonate or succinate ligands, forming Ti₆ clusters. A photochromic effect was observed upon irradiating the crystals, and the color of the crystals was changed from transparent to gray. Photodegradation of the methyl orange in aqueous dispersions of microcrystals of compounds 1 and 2 were carried out under UV cut white light with the assistance of H₂O₂. Compound 2 exhibited higher photocatalytic activity than 1, which might be related to the smaller angles of μ ₂-O bridge in 2.     

Lowervalent hexaniobate cluster in aqueous HCl: an equilibrium redox study

Summary It has been established⁽¹⁾ that hydrated niobium(V) oxide is, in fact, hexameric isopolyniobic acid, H₈Nb₆O₁₉·xH₂O, containing a protonated oxoniobate(V) cluster. It has also been shown^(2,3) that the stoichiometric and nonstoichiometric oxides as well as niobates, soluble or insoluble, formed under various conditions, are really derivatives of H₈Nb₆O₁₉. The amphoteric H₈Nb₆O₁₉ is soluble in conc. H₂SO₄ maintaining its hexanuclear structure⁽⁴⁾ and exists in the form of a SO₃ adduct of H₈Nb₆O₁₉. In the latest communication⁽⁵⁾ the hexameric cluster has been shown to exist even in the subnormal niobium oxidation states. The aqueous H₂SO₄ solution of niobium(V) when reduced with zinc forms various dark red-brown crystalline salts of the anion [Nb₆O₇(O·SO₃)₁₂]^16–. This cluster anion has niobium in an average nonintegral oxidation state of +3.67 and the Nb₆O₁₉ unit is coordinated to a maximum of twelve SO₃ groups. The present communication describes the potentiometric investigation of the reduced oxoniobate cluster in aqueous HCl. There are reports that strongly acidic niobium(V) solutions are reduced either electrolytically or by metals^(6–9). These workers proposed that niobium(III) was formed in solution although no detailed investigation on the species was made.     

Ferrocene-Based Actinide Clusters: Synthesis,Crystal Structures,and Characterization

The polynuclear metal clusters continually attract wide interest due to their intriguing structures and potential applications in various scientific fields. Here, four actinide clusters have been synthesized by the utilization of multifunctional ligand ferrocenecarboxylic acid (HFcc) and Th⁴⁺/U⁴⁺ ions by solvent evaporation or solvothermal synthesis strategies in different solvents. Therein, compounds 1 , 2 and 4 feature similar [An₆(μ₃-O)₄(μ₃-OH)₄]¹²⁺ cores, which are further coordinated by 12 Fcc⁻ ligands and different solvent molecules. The U₆Fe₁₂ cluster of compound 4 is linked by four free HFcc molecules via multiple hydrogen bonding to form a supramolecular cluster [U₆(μ₃-O)₄(μ₃-OH)₄(Fcc)₁₂(H₂O)₄] ⋅ 4HFcc. The cluster core of compound 3 is a μ₃-O²⁻ bridged [U₃(μ₃-O)]¹⁰⁺ unit, which is further coordinated by 10 Fcc⁻ ligands via three kinds of coordination modes. It is worth noting that multifunctional Fcc⁻ ligand not only endows compound 1 a main redox wave at E_1/2=0.720 V in CH₂Cl₂/DMF solution, but also enables it to exhibit aggregation-induced emission (AIE) property.     

From Specific γ-CD/[Nb6Cl12(H2O)6]2+ Recognition to Biological Activity Tuning

Specific molecular recognition of γ-cyclodextrin (γ-CD) by the cationic hexanuclear niobium [Nb₆Cl₁₂(H₂O)₆]²⁺ cluster complex in aqueous solutions results in a 1:1 supramolecular assembly {[Nb₆Cl₁₂(H₂O)₆]@γ-CD}²⁺. NMR spectroscopy, isothermal titration calorimetry (ITC), and ESI-MS were used to study the interaction between the inorganic cluster and the organic macrocycle. Such molecular association affects the biological activity of [Nb₆Cl₁₂(H₂O)₆]²⁺, decreasing its cytotoxicity despite enhanced cellular uptake. The 1:1 stoichiometry is maintained in solution over a large window of the reagents’ ratio, but crystallization by slow evaporation produces a 1:2 host–guest complex [Nb₆Cl₁₂(H₂O)₆@(γ-CD)₂]Cl₂ ⋅ 20 H₂O featuring the cluster encapsulated between two molecules of γ-CD. The 1:2 complex was characterized by XRD, elemental analysis, IR spectroscopy, and thermogravimetric analysis (TGA). Quantum chemical calculations were performed to model host–guest interaction.     

Ternäre Chloride mit trigonal-bipyramidalen Clustern: [M5(C2)]Cl9 (M = La?Pr)

Ternary Chlorides with Trigonal-Bipyramidal Clusters: [M₅(C₂)]Cl₉ (M = La? Pr) The chlorides [M₅(C₂)]Cl₉ (M = La? Pr) are obtained by metallothermic reduction of the respective trichlorides MCl₃ with caesium in the presence of the lanthanide metal and carbon in sealed niobium ampoules at 800°C. They contain trigonal-bipyramidal clusters [M₅(C₂)] crystallizing with the triclinic crystal system. Only seven of the nine edges of the trigonal bipyramids are brigded by chloride (Clⁱ). Each cluster is surrounded by twelve terminal ligands (Cl^a) so that units of the composition [M₅(C₂)Cl₇ⁱ]Cl₁₂^a have to be considered. These are connected not only via Cl^i–a and Cl^a–a–a bridges. Rather, Cl^a–a (one linear and one bent) and Cl^i–i bridges are also observed.     

Octahedral Niobium Thiocyanato Complexes Containing [Nb6Cl9O3] Cluster Core: Syntheses, Crystal Structures and Evidences of NCS Ligand Exchange

Two isomers (cis and trans) of [Nb₆Cl₉O₃(NCS)₆]^5– niobium cluster complexes characterized by an ordered arrangement of oxygen and chlorine ligands over the 12 inner positions in the cluster core were prepared by reaction of Cs₂LaNb₆Cl₁₅O₃ and ScNb₆Cl₁₃O₃ solid state compounds with aqueous solution of potassium thiocyanate. The cis and trans isomers (idealized C _{2 v} and D ₃ symmetry, respectively) crystallize with counter cations and water molecules to form the following salts: Cs_4.75K_0.25[Nb₆Cl₉O₃(NCS)₆] · 5.5H₂O (1) and Cs_2.5K_2.5[Nb₆Cl₉O₃(NCS)₆] · 2H₂O (2), respectively. The trans isomer is ordered in structure 1 (s.g.: C2/c), while in the structure of 2 (s.g.: Pnma), the cis isomer is randomly disordered over two positions that correspond one to each other by a mirror plane. Interestingly, the treatment of thiocyanato complexes cis and trans with hydrochloric acid led to substitution of (NCS)^– ligands by Cl^– and to formation of soluble complexes [Nb₆Cl₉O₃Cl₆]^5–. The cesium salt of trans-[Nb₆Cl₉O₃Cl₆]^5– was crystallized as Cs₅[Nb₆Cl₁₅O₃] · CsCl · 7H₂O (3) and structurally characterized. Indeed, the formation of soluble [Nb₆Cl₉O₃(NCS)₆]^5– intermediates is a necessary step towards the formation of soluble anions.     

Reversible double insertion of aryl isocyanates into the Ti-O bond of titanium(IV) isopropoxide

The insertion of phenyl isocyanate into titanium isopropoxide leads to the formation of a dimeric complex [Ti(OⁱPr)₂(μ-OⁱPr){C₆H₅N(OⁱPr)CO}]₂ (1) which has been structurally characterized. Reaction of titanium isopropoxide with two and more than 2 equiv. of phenyl isocyanate is complicated by competitive, reversible insertion between the titanium carbamate and titanium isopropoxide. The ligand formed by insertion of phenyl isocyanate into the titanium carbamate has been structurally characterized in its protonated form C₆H₅N{C(OⁱPr)O}C(O)N(H)C₆H₅ (3aH). Insertion into the carbamate is kinetically favored whereas insertion into isopropoxide gives the thermodynamically favored product.     

Coordination of mono- and diamines to titanium and zirconium alkoxides

The structural chemistry of crystalline adducts M₂(OR)₈(amine)₂ (M = Ti: OR = OⁱPr, amine = NH₂CH₂Ph, NH₂Bu; M = Ti: OR = OEt, amine = piperidine; M = Zr: OR = OⁱPr, amine = NH₂CH₂Ph, NH₂C₆H₁₁) is discussed. The adducts were obtained by reaction of Ti(OEt)₄ or M(OⁱPr)₄ with primary or secondary amines. The monoamine adducts are centrosymmetric dimers in which the amines are coordinated axially to the M₂μ-OR)₂ ring and hydrogen-bonded to neighboring alkoxo ligands. The adducts are sufficiently stable if the hydrogen bond is strong. ¹⁵N NMR studies revealed that the amines are also coordinated in solution. Coordination polymers were obtained when diamines with two terminal NH₂ groups are reacted with Ti(OⁱPr)₄. The general structure is the same as that of Ti₂(OⁱPr)₈(RNH₂)₂. However, the diamines bridge the Ti₂(OⁱPr)₈ units. When Zr(OⁱPr)₄ was reacted with NH₂CH₂CH₂NHMe, the adduct Zr₂(OⁱPr)₈[NH₂CH₂CH₂NHMe]₂ was obtained where only the NH₂ group is coordinated.     

{Nb288O768(OH)48(CO3)12}: A Macromolecular Polyoxometalate with Close to 300 Niobium Atoms

A protein‐sized (ca. 4.2×4.2×3.6 nm³) non‐biologically derived molecule {Nb₂₈₈O₇₆₈(OH)₄₈(CO₃)₁₂} ( Nb₂₈₈ ) containing up to 288 niobium atoms has been obtained, which is by far the largest and the highest nuclearity polyoxoniobate (PONb). Particularly, in terms of metal nuclearity number, Nb₂₈₈ is the second largest cluster so far reported in classic polyoxometalate chemistry (V, Mo, W, Nb, and Ta). Nb₂₈₈ can be described as a giant windmill‐like cluster aggregate of six nanoscale high‐nuclearity PONb units {Nb₄₇O₁₂₈(OH)₆(CO₃)₂} ( Nb₄₇ ) joined together by six additional Nb ions. Interestingly, the 47‐nuclearity Nb₄₇ units generated in situ can be isolated and bridged by copper complexes to form an inorganic–organic hybrid three‐dimensional PONb framework, which exhibits effective catalytic activity for hydrolyzing nerve agent simulant of dimethyl methylphosphonate. The unique Nb₄₇ cluster also provides a new type of topology to very limited family of Nb‐O clusters.     

Synthesis and characterization of bis(<Emphasis Type="Italic">O,O</Emphasis>′-diisopropylmonothiophosphato)nickel(II) adducts and molecular structures of bis(pyridine)bis(<Emphasis Type="Italic">O,O</Emphasis>′-diisopropylmonothiophosphato)nickel(II) complex

The present work demonstrates the synthesis and characterization of adducts with bis(O,O′-diisopropylmonothiophosphato)nickel(II) complex, Ni{S(O)P(OⁱPr)₂}₂(L) _n (n = 2, L = pyridine, 2-picoline, 3-picoline; n = 1, L = 2,2′-bipyridyl and 1,10-phenanthroline). The crystallographic investigation of Ni{S(O)P(OⁱPr)₂}₂(C₅H₅N)₂ reveals distorted octahedral geometry around the central nickel(II) atom. The monothiophosphate moieties show anisobidentate coordination to the central metal, while the pyridine ligands are in cis positions. These nickel(II) adducts were characterized by elemental analysis, a range of spectroscopic techniques, and magnetic susceptibility measurement.