The Formation and Stability of the [FePy3Cl3]· Py Clathrate in the Pyridine–Iron(III) Chloride System: Phase Diagram and Solid–Gas Equilibria Study

The phase diagram of the pyridine–iron(III) chloride system has been studied for the 223–423 K temperature and 0–56 mass-% concentration ranges using differential thermal analysis (DTA) and solubility techniques. A solid with the highest pyridine content formed in the system was found to be an already known clathrate compound, [FePy₃Cl₃]·Py. The clathrate melts incongruently at 346.9 ± 0.3 K with the destruction of the host complex: [FePy₃Cl₃]·Py_(solid)=[FePy₂Cl₃]_(solid) + liquor. The thermal dissociation of the clathrate with the release of pyridine into the gaseous phase (TGA) occurs in a similar way: [FePy₃Cl₃]·Py_(solid)=[FePy2Cl₃]_(solid) + 2 Py_(gas). Thermodynamic parameters of the clathrate dissociation have been determined from the dependence of the pyridine vapour pressure over the clathrate samples versus temperature (tensimetric method). The dependence experiences a change at 327 K indicating a polymorphous transformation occurring at this temperature. For the process ${1 \over 2}[\hbox{FePy}_{3}\hbox{Cl}_{3}]\cdot \hbox{Py}_{\rm (solid)} = {1 \over 2}[\hbox{FePy}_{2}\hbox{Cl}_{3}]_{\rm (solid)} + \hbox{Py}_{\rm (gas)}$ in the range 292–327 K, ΔH $^{0}_{298}$ =70.8 ± 0.8 kJ/mol, ΔS $^{0}_{298}$ =197 ± 3 J/(mol K), ΔG $^{0}_{298}$ =12.2 ± 0.1 kJ/mol; in the range 327–368 K, ΔH $^{0}_{298}$ =44.4 ± 1.3 kJ/mol, ΔS $^{0}_{298}$ =116 ± 4 J/(mol K), ΔG $^{0}_{298}$ =9.9 ± 0.3 kJ/mol.     

Experimental Study and 3D Modeling of the Phase Diagram of the Ag–Sn–Se System

In connection with the contradictoriness of literature data, phase equilibria in the Ag–Sn–Se system were restudied by differential thermal analysis and X-ray powder diffraction analysis. A number of polythermal sections and the isothermal section at room temperature of the phase diagram were constructed, and a projection of the liquidus surface was built. The primary crystallization fields of phases and the types and coordinates of in- and monovariant equilibria were determined. It was demonstrated that, in the system, two ternary compounds, Ag₈SnSe₆ and Ag_xSn_{2 – x}Se₂ (0.84 < x < 1.06), form. The former melts congruently at 1015 K and undergoes a polymorphic transformation at 355 K, and the latter melts with decomposition by a peritectic reaction at 860 K. The formation of the compound Ag₂SnSe₃, which was previously reported in the literature, was not confirmed. Based on the phase diagrams of boundary binary systems and the results of the differential thermal analysis of a limited number of samples of the ternary system, equations were obtained for calculation and 3D modeling of the liquidus and phase-separation surfaces.     

Phase Equilibria in the System Fe2O3–V2O5 –WO3 in the Solid State

DTA and X-ray phase diffraction methods were used to construct a solidus area projection onto the component concentration triangle plane of the system Fe₂ O₃-V₂ O₅-WO₃. This revised version was published online in August 2006 with corrections to the Cover Date.     

Reactivity in Air of SbVO5 Towards MoO3 and Phase Equilibria in the SbVO5–MoO3 System in the Solid State

The use of XRD and DTA methods has allowed studies on the interaction of the SbVO₅ and MoO₃, taking place in the solid state and in the medium of ambient air. The experimental results of XRD and DTA for all the samples showed the presence of a novel phase, i.e. Sb₃V₂Mo₃O₂₁ apart from various amounts of MoO₃ and V₉Mo₆O₄₀ or SbVO₅ and V₂O_5(s.s.). The SbVO₅–MoO₃ system is not a real two-component system over the entire range of component concentrations up to the solidus line. This revised version was published online in July 2006 with corrections to the Cover Date.     

Calculation of the Liquid–Solid Phase Diagram and the Thermodynamic Quantities of the Binary System of Tetradecane and Hexadecane Using the Mean Field Theory

Journal of Solution Chemistry - The T???x phase diagram of a binary system of tetradecane?+?hexadecane is calculated using the Landau phenomenological model....     

Synthesis and crystal structure of [Mo3S4(Dppen)3Cl3]PF6 · 1.5CH2Cl2 and [W3S4(Dppe)3Br3]2ZnBr4 · 5.5CH3CN

New cluster complexes [Mo₃S₄(Dppen)₃Cl₃]PF₆ · 1.5CH₂Cl₂ (Dppen = cis-Ph₂PCH=CHPPh₂) (I) and [W₃S₄(Dppe)₃Br₃]₂(ZnBr₄)₂ · 5.5CH₃CN (Dppe = Ph₂PCH₂CH₂PPh₂) (II) were synthesized. Their molecular and crystal structures were determined by X-ray diffraction. Diphoshine ligands in the complexes I and II are coordinated in the bidentate mode, providing an arrangement of three chelate rings, giving rise to chirality.     

Phase Diagram of the Benzene–Dinitratotetrapyridinecopper(II) (Guest–Host) System and Thermodynamic Parameters for the Hostβ2Guest Clathrate Dissociation

In the first part of the work, thephase diagram of the benzene -ndash;[CuPy⁴(NO³)²] system has beendetermined in the -100 to +200 °C temperaturerange using DTA and solubility techniques. The onlycompound found in the system is the[CuPy⁴(NO³)²] 2C⁶H⁶clathrate. It is stable up to a temperature of+104.2(5) °C at which it melts incongruently togive liquid and the solid [CuPy⁴(NO³)²]host phase. At 146.1(5) °C exfoliation into twoliquid phases is observed, with the composition of themonotectic point being close to that of the clathrate.In the second part of the work, thermodynamicparameters of the clathrate dissociation have beendetermined from benzene vapour pressure strainmeasurements. For the process1/2 [CuPy⁴(NO³)²]2C⁶H⁶(solid) = 1/2 [CuPy⁴(NO³)²] (solid) +C⁶H⁶ (gas) H° = 45.3(3) kJ/mole; S₂₉₈° = 126(1) J/(mole K); G₂₉₈° = 7.7(5) kJ/mole.     

Study on the Phase Diagram of CsCl-CeCl3-HCl(11%)-H2O System and the Properties of the Compounds

The equilibrium solubility of CsCl-CeCl3-HCl(11%)-H2O qua-ternary system at 25℃ has been determined by the physicchemical analysis method ,and the phase diagram was plotted, Two new double salts 3CsCl.CeCl3.3H2O and CsCl.CeCl3.4H2O obtained from the complicated system were identified and characterized by XRD,TG-DTA ,DSC,UV and fluorescence spectroscopy, Studies on the fluorescence excitation and emission show that 3CsCl.CeCl3.3H2O and CsCl.CeCl3.4H2O have upconversion luminescence of infrared-visible range,and the upconversion emission intensity increases with the increase of ratio of CeCl3 in CsCl.     

Host–Guest Chemistry in the Gas Phase: Complex Formation of Cucurbit[6]uril with Proton-bound Water Dimer

The hydration of cucurbit[6]uril (CB[6]) in the gas phase is investigated using electrospray ionization traveling wave ion mobility mass spectrometry (ESI-TWIM-MS). Highly abundant dihydrated and tetrahydrated species of diprotonated CB[6] are found in the ESI-TWIM-MS spectrum. The hydration patterns of the CB[6] ion and the dissociation patterns of the hydrated CB[6] ion indicate that two water molecules are bound to each other, forming a water dimer in the CB[6] complex. Ion mobility studies combined with the structures calculated by density functional theory suggest that the proton-bound water dimer is present as a Zundel-like structure in the CB[6] portal, forming a hydrogen bond network with carbonyl groups of the CB[6]. When a large guest molecule is bound to a CB[6] portal, water molecules cannot bind to the portal. In addition, the strong binding energy of the water dimer blocks the portal, hindering the insertion of the long alkyl chain of the guest molecule into the CB[6] cavity. With small alkali metal cations, such as Li⁺ and Na⁺, a single water molecule interacts with the CB[6] portal, forming hydrogen bonds with the carbonyl groups of CB[6]. A highly stable Zundel-like structure of the proton-bound water dimer or a metal-bound water molecule at the CB[6] portal is suggested as an initial hydration process for CB[6], which is only dissolved in aqueous solution with acid or alkali metal ions.

Isomerization of [In(H2O)3Cl3] · 18C6. Crystal structure of [ mer -In(H2O)3Cl3] · 18C6 and [ fac -In(H2O)3Cl3] · 18C6 · 2H2O

The complex [mer-In(H₂O)₃Cl₃] · 18C6 (I) was isolated from the InCl₃-H₂O-Solv-18C6 solutions (Solv = MeOH, EtOH, THF). The second crystallization from mother solutions resulted in [fac-In(H₂O)₃Cl₃] · 18C6 · 2H₂O (II). The crystal and molecular structures of isomers I, II were identified by the powder X-ray diffraction, IR, and X-ray diffraction methods. Although complexes I, II have different compositions, they have the chain structure. The thermal decomposition of complexes I, II was studied. Original Russian Text ? A.B. Ilykhin, Zh.V. Dobrokhotova, S.P. Petrosyants, 2008, published in Koordinatsionnaya Khimiya, 2008, Vol. 34, No. 9, pp. 651–656.     

Structure and synthesis of nitrosoruthenium trans -diammines [Ru(NO)(NH3)2Cl3] and [Ru(NO)(NH3)2(H2O)Cl2]Cl·H2O

A DTA study of thermal decomposition of (NH₄)₂[Ru(NO)Cl₅] in helium atmosphere has been carried out, a synthetic procedure for preparation of the trans-diammine complex mer-[Ru(NO)(NH₃)₂Cl₃] (I) with yield ∼70% has been developed. On re-crystallization of I from aqueous solution a trans-aquanitroso complex [Ru(NO)(NH₃)₂Cl₂(H2O)]Cl·H₂O (II) has been isolated. The structures of the compounds have been determined by single crystal X-ray diffraction: space group Pbcn, a = 6.607(1) ? b = 11.255(2) ? c = 9.878(2) ? (I) and space group Ima2, a = 8.3032(3) ?, b = 8.0890(2) ?, c = 15.9192(5) ? II). Original Russian Text Copyright ? 2008 by M. A. Il’in, V. A. Emel’yanov, and I. A. Baidina __________ Translated from Zhurnal Strukturnoi Khimii, Vol. 49, No. 6, pp. 1128–1136, November–December, 2008.     

Synthesis and structural characterisation of the palladium N-heterocyclic carbene cluster complexes [Pd3(μ-CO)3(NHC)3] and [Pd3(μ-SO2)3(NHC)3]

The reduction of trans-[Pd(NHC)₂Cl₂] (NHC = IMes, 1,3-bis(2,4,6-trimethylphenyl)imidazol-2-ylidene; IⁱPr₂ = 1,3-bis-isopropylimidazol-2-ylidene) with potassium graphite under an atmosphere of CO affords the palladium NHC carbonyl clusters [Pd₃(μ-CO)₃(NHC)₃] (NHC = IMes, 1; IⁱPr₂, 3). Treatment of 1 with SO₂ at room temperature yields the bridging SO₂ complex [Pd₃(μ-SO₂)₃(IMes)₃] (4) in quantitative yield. Complexes 1, 3 and 4 have been structurally characterised by X-ray crystallography.     

氮氧自由基-锌配合物[Zn(NIT3Py)2Cl2]的合成、结构和磁行为

A Zn(Ⅱ) complex with nitronyl nitroxide radicals [Zn(NIT3Py)₂Cl₂] (1) (NIT3Py=2-(3′-pyridinyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide) has been synthesized and structurally characterized by X-ray diffraction crystal structure determination method. The complex has a mononuclear-metal structure in which each Zn(Ⅱ) ion adopts a distorted tetrahedral geometry and is coordinated by two Cl^- anions and two pyridyl-N atoms from two NIT3Py radical ligands. The magnetic measurements show the weak antiferromagnetic interaction between the nitroxide radicals through the diamagnetic Zn(Ⅱ) ion. CCDC: 292363.     

Synthesis and structure of gold and copper complexes: [Ph3PhCH2P]+[AuCl4]?, [NH(C2H4OH)3]+[AuCl4]? · H2O, and [Ph3EtP] 2+ [Cu2Cl6]2?

Triphenylbenzylphosphonium tetrachloroaurate (I) and triethanolammonium tetrachloroaurate hydrate (II) were prepared by reacting tetrachloroauric acid in acetone with triphenylbenzylphosphonium and triethanolammonium, respectively. Triphenylethylphosphonium hexachlorodicuprate (III) was synthesized from triphenylethylphosphonium chloride and copper chloride in acetone. The crystal structures of complexes I to III were determined by single-crystal X-ray diffraction. The phosphorus atoms in complex I have a nearly undistorted tetrahedral coordination (CPC, 108.3°–110.6°; P-C, 1.788–1.793 ?). The coordination of nitrogen atoms in the cations of complex II is a distorted tetrahedron (CNC, 111.7°–112.4°). The square coordination of aurum in I and II is only slightly distorted: the ClAuCl angles are 89.6°–90.3° (I) and 89.5°–90.6° (II) and the Au-Cl distances are 2.256–2.278 ? I) and 2.280–2.285 ? (II). The phosphorus atoms in complex III are tetracoordinated (CPC, 106.34°–111.73°; P-C, 1.790–1.795 ?). The copper atoms in III have a distorted tetrahedral coordination (ClCuCl, 98.48°–144.85°; Cu-Cl, 2.1999–2.3263 ?). The central fragment Cu₂Cl₂ in the anion of complex III is bent relative to the Cu₂ axis (the chlorine atom deviates from the Cu₂Cl plane by 0.27 ?).     

Synthesis and crystal structure of [W3S4(Acac)3(PPh3)3]PF6 · 0.5CHCl3 and [W3S4(Hfac)3(PPh3)2Br] · 2CHCl3

New cluster complexes [W₃S₄(Acac)₃(PPh₃)₃]PF₆ · 0.5CHCl₃ (Acac = CH₃C(O)CHC(O)CH₃) (I) and [W₃S₄(Hfac)₃(PPh₃)₂Br] · 2CHCl₃ (Hfac = CF₃C(O)CHC(O)CF₃) (II) were synthesized. Their molecular and crystal structures were determined by X-ray diffraction. The cis-cis type of coordination of acetylacetonate and hexafluoroacetylacetonate ligands in I and II, respectively, was established, and the PPh₃ ligands were found in the trans-positions with respect to the “capping” sulfide ligand (μ³-S).     

Ligand substitution in the cluster complex [Mo3S7Cl6]2?: Synthesis and crystal structure of (Et4N)[Mo3S7Cl5(CH3CN)]

The crystal structure of the new cluster complex (Et₄N)₂[Mo₃S₇Cl₆] · CH₃CN · H₂O (I) was determined. Heating of a solution of I in CH₃CN under solvothermal conditions (120°C) induces replacement of one Cl⁻ ligand by CH₃CN to give (Et₄N)[Mo₃S₇Cl₅(CH₃CN)] (II). The product was also studied by X-ray diffraction analysis.     

Theoretical Study on the Structures and Stability of Isomers and Complex of [Si, C, O, O] System

Introduction[Si,C ,O ,O]systemhasattractedmuchattentioninthefieldsofchemistryandmaterials1 3becauseofthefollow ingseveralcauses .First,theinterestisthepotentialimpor tanceininterstellarspace .Heretofore ,SiC ,SiOandCOhavebeendetectedwithintheinterstellarmediumformanyyears,butno [Si,C ,O ,O]isomerswereobservedinthenebulae .FormanySi containingsystemshavebeenstudiedexperimentallyandtheoretically ,4 8andinviewofthepossibleexistenceofthe [Si,C ,O ,O]radicalininterstellarspace ,weselectthe…     

Crystal Structure and Thermodynamic Stability of the [Hg(Pyridine)4(NO3)2] · 2(Pyridine) Inclusion Compound

The studied compound belongs to the family of [MPy₄X ₂] . 2Py isomorphous clathrates. Its crystal structure exhibits a van der Waals architecture formed by neutral [HgPy₄(NO₃)₂] host molecules, with the guest pyridine molecules included in the cavities of the host lattice. The host complex is formed by coordination of four pyridines, located near the equatorial plane, and two nitrates, located axially, to the Hg(II) cation. One of nitrates ligates as a monodentate ligand and another as a bidentate. The coordination polyhedron is HgN₄O₃, with average Hg—N_Py and Hg—O_nitrate distances of 2.38(5) and 2.68(1) Å, respectively. The crystal structure is complicated with a superlattice and the crystal symmetry reduced to monoclinic, as compared to the structure usually occurring in the [MPy₄X₂] . 2Py clathrates. The pyridine vapor pressure over the clathrate was measured in the 293--369 K temperature range by the static tensimetric method. Thermodynamic parameters of the clathrate dissociation were calculated from these data. For the reaction 1/3[HgPy₄(NO₃)₂] . 2Py_solid=1/3[HgPy₃(NO₃)₂] _solid + Py_gas the parameters are as follows: H⁰_av = 49.4(2) kJ/mol, S ⁰_av = 127(2) J/(mol K) and G⁰₂₉₈=11.4(3) kJ/mol. The results are compared with previously reported data on compounds of the [MPy₄(NO₃)₂] . 2Py series.     

Crystal structure of solvate [Cd2L2Cl4]·CH2Cl2 (L = pyrazolylquinoline, the derivative of monoterpenoid (+)-3-carene) and photoluminescence of chiral complex CdLCl2

Using the single crystal X-ray diffraction data (150 K, Bruker X8 Apex CCD autodiffractometer, MoK α radiation), the crystal structure of the [Cd₂L₂Cl₄]·CH₂Cl₂ (L = pyrazolylquinoline, the derivative of monoterpenoid (+)-3-carene) compound is determined. Crystals are monoclinic, unit cell parameters are: a = 10.7005(4) ?, b = 16.8491(4) ?, c = 11.9658(4) ?, β = 93.308(1)°, P2₁ space group. The structure is formed from discrete acentric molecules of a binuclear [Cd₂L₂Cl₄] complex and uncoordinated CH₂Cl₂ molecules. The Cd²⁺ ions coordinate N atoms of bidentate chelating ligands L, which leads to the closure of two five-membered chelate CdN₃C rings. The coordination sphere of Cd atoms also includes three Cl atoms (two bridging and one terminal), consequently, two CdCl₃N₂ coordination sites and a Cd₂Cl₂ metal ring are formed. The Cl₃N₂ polyhedra have the form of distorted tetragonal pyramids. The CH₂Cl₂ molecules located in the channels formed by the complexes are linked with them by weak H-bonds. The excitation spectra of L and the CdLCl₂ compound contain bands with λ_max of 352 nm and 360 nm respectively. At 300 K and λ_excit 350 nm, in the photoluminescence spectrum of L a rather intense broad split band with λ_max 372 nm and 386 nm is observed. The photoluminescence spectrum of the CdLCl₂ compound contains a broad band with λ_max 418 nm. The photoluminescence intensity of this compound is significantly lower than that of L.