The X-ray crystal structure of Hg(C6H4OMe-4) (C6F5): an unexpected twist

The X-ray crystal structure of Hg(C₆H₄OMe-4)(C₆F₅) reveals the first example of perpendicular rings in a diarylmercurial complex. Hg(C₆H₄OMe-4) (C₆F₅) crystallizes in monoclinic space group P2₁/c with a = 11.4004(14), b = 7.5683(9), c = 15.0247(18) Å, = 104.849 (2)° with calculated density 2.517 g cm^–3 for Z = 4.     

Very facile decarboxylation syntheses of polymethoxyphenylmercury compounds

The mercurials RHgO₂CR [R = 2,6-(MeO)₂C₆H₃, 2,3,4-(MeO)₃C₆H₂, or 2,4,6-(MeO)₃C₆H₂], RHgO₂CMe and R₂Hg [R = 2,4,6-(MeO)₃C₆H₂] have been obtained in good yield from decarboxylation reactions between mercuric acetate and the corresponding polymethoxybenzoic acids in aqueous methanol at room temperature.     

N- versus P-coordination in bis(amino)cyclodiphosph(III)azane complexes of aluminum

The reaction of the bis(amino)cyclodiphosph(III)azane, cis-{(tBuNH)(2)(PNtBu)(2)}, with AlMe(3), AlClMe(2), AlCl(2)Me, and AlCl(3) is reported. The less Lewis acidic compound AlMe(3) forms the adduct cis-[(tBuNH)(2)(PNtBu){P.(AlMe(3))NtBu}] (1), in which the aluminum atom is exclusively coordinated to one phosphorus atom. At elevated temperatures AlMe(3) undergoes migratory exchange between the two phosphorus atoms, but no methane elimination is observed. By using the more Lewis acidic compound AlClMe(2) the P-coordinated compound cis-[(tBuNH)(2)(PNtBu){P(AlClMe(2))NtBu}] (2) can be obtained at low temperatures. Compound 2 rearranges irreversibly to a product in which the AlClMe(2) group is coordinated by one exo-cyclic nitrogen atom. A concomitant 1,2-H shift from this nitrogen atom onto the phosphorus atom is observed. The N-coordinated rearrangement product slowly decomposes via a P-N bond cleavage in solution. Reaction of the even more Lewis acidic compounds AlCl(2)Me and AlCl(3) finally led to stable adducts, cis-[(tBuNH)(PNtBu)(tBuNAlCl(2)Me){P(H)NtBu}] (3), and cis-[(tBuNH)(PNtBu)(tBuNAlCl(3)){P(H)NtBu}] (4), in which the aluminum atoms are N-coordinated by a tBuN=PH unit.     

Syntheses and structures of N-polyfluorophenyl- and N,N′-bis(polyfluorophenyl)ethane-1,2-diaminato(1- or 2-)platinum(II) complexes

The reaction of [PtX₂(L)] (X = Cl, Br, I; L = NH₂CH₂CH₂NY₂; Y = Et, Me) with thallium(I) carbonate and a polyfluorobenzene (RF) in pyridine (py) yields the platinum(II) complexes, [Pt{N(R)CH₂CH₂NY₂}X(py)] (R = C₆F₅, 4-HC₆F₄, 4-BrC₆F₄, or 4-IC₆F₄, Y = Et (1), Me (2), X = Cl, Br or I) in an improved synthesis. From the reaction of [PtCl₂(H₂NCH₂)₂)] with Tl₂CO₃ and 1,2,3,4-tetrafluorobenzene or 2-bromo-1,3,4,5-tetrafluorobenzene in py, the new complexes [Pt(NRCH₂)₂(py)₂] (3) (R = C₆H₂F₃-2,3,6 and C₆HBrF₃-2,3,5,6) have been isolated but the latter preparation also gave product(s) with a 4-bromo-2,3,5-trifluorophenyl group. From an analogous preparation in 4-ethylpyridine (etpy), [Pt(N(4-HC₆F₄)CH₂)₂(etpy)₂] (4) was obtained. The X-ray crystal structures of (3) (R = C₆HBrF₃-2,3,5,6) and (4) were determined as well as that of the previously prepared (3) (R = 4-BrC₆F₄) and a more precise structure of (3) (R = 4-HC₆F₄) has been obtained.     

Organoamido- and aryloxo-lanthanoids. XIII [1]. Organometallic compounds of the lanthanoids. CV [2]. New Lanthanoid(III) Complexes with Pyrazolate Ligands

The complexes Er(Me₂pz)₃(thf) and Ln(Ph₂pz)₃(thf)_n (Ln = Sc, Y, Gd, Er, n = 2; Ln = Lu, n = 3) (Me₂pz^? = 3,5-dimethylpyrazolate, thf = tetrahydrofuran, Ph₂pz^? = 3,5-diphenylpyrazolate) have been prepared by reaction of the lanthanoid metal with bis(pentafluorophenyl)mercury and the pyrazole in thf. The Ln(Ph₂pz)₃(thf)₂ complexes are considered to be eight coordinate with three η²-Ph₂pz ligands. Other lanthanoid pyrazolate complexes, Y(pz)₃(thf)₂, La(Me₂pz)₃(thf), Cp₂Ln(Me₂pz)(thf)_n (Ln = Y, Lu, n = 0; Ln = Lu, n = 1), (C₅Me₅)₂Y(pz)(thf), (C₅Me₅)₂Y(Mepz)(thf), (C₅Me₅)₂Y(Me₂pz)(thf)₂ (pz^? = pyrazolate, Mepz^? = 3-methylpyrazolate, Cp = cyclopentadienyl) have been synthesized by reaction of LnCl₃, Cp₂LnCl, or (C₅Me₅)₂LnCl with the appropriate sodium pyrazolate in thf. The structure of Ln(Me₂pz)₃(thf) (Ln = La or Er) is considered to be a symmetrical dimer with four chelating and two bridging Me₂pz groups, and two bridging thf ligands, whereas the cyclopentadienyl complexes are most likely dimers with bridging pyrazolate groups, and lattice thf of solvation.     

Gain measurements versus theory for the ACO storage ring laser

We discuss the gain measurements made on the Orsay storage ring free electron laser, and show that the peak measured gain is identical to that predicted by a modified theory which takes into account the electron trajectory distortions. This is the first free electron laser experiment in which the quality of the data is sufficiently good to permit a detailed verification of the Madey theorem.     

Charge‐Separated and Molecular Heterobimetallic Rare Earth–Rare Earth and Alkaline Earth–Rare Earth Aryloxo Complexes Featuring Intramolecular Metal–π‐arene Interactions

A new family in town! Treatment of a rare‐earth metal (Ln) and either a potential divalent rare‐earth metal (Ln′) or an alkaline earth metal (Ae) with 2,6‐diphenylphenol (HOdpp) at elevated temperatures (200–250 °C) afforded heterobimetallic aryloxo complexes (see figure). Both a charge‐separated species, [(Ln′/Ae)₂(Odpp)₃][Ln(Odpp)₄], and a neutral species, [AeEu(Odpp)₄], were obtained and crystallographically characterised.

     

Intramolecular Metal–Fluorocarbon Coordination,C?F Bond Activation and Lanthanoid–Fluoride Clusters with Tethered Polyfluorophenylamide Ligands

Activating C? F bonds : Strong metal–fluorocarbon coordination in complexes of electropositive metals (e.g., Na, K, Yb) with chelating polyfluorophenyl‐substituted amide ligands is a precursor to C? F bond activation and fluoride abstraction when M=Yb^II, giving heteroleptic Yb^III fluoride clusters (see scheme).

     

Preparations,structures and thermal decomposition of some bis(pentafluorobenzoato)dioxouranium(VI) complexes

Reaction Of UO₂(O₂CCH₃)₂ with pentafluorobenzoic acid yields UO₂(O₂CC₆F₅)₂, which has been converted into the solvated complexes UO₂(O₂CC₆F₅)₂L₂·S [L₂ = 2,2′-bipyridyl (bpy), S = 0.33 (PhH) or 0.07 (t-BuOH); L = Ph₃PO, S = t-BuOH; L = Ph₃AsO, S = 0.40 (t-BuOH)] and the solvent free UO₂(O₂CC₆F₅)₂L₂ [L₂ = bpy; L = Ph₃PO]. The crystal structure of UO₂(O₂CC₆F₅)₂bpy (orthorhombic, space group P2₁2₁2₁; a = 18.45(2), b = 18.94(2), c = 7.069(8) Å, Z = 4] reveals distorted hexagonal bipyramidal stereochemistry with a trans UO₂ group, chelating pentafluorobenzoate ligands, and chelating 2,2′-bipyridyl, which is significantly displaced from the hexagonal plane. The structure of UO₂(O₂CC₆F₅)₂(OPPh₃)₂·t-BuOH [rhombohedral, space group R3; a = 21.51(3) Å, α = 117.28(5)°, Z = 3] shows trans UO₂, pseudo trans Ph₃PO ligands, and one unidentate and one disordered chelating pentafluorobenzoate ligand, whilst t-BuOH could not be located because it is highly disordered. Relationships between ν (CO₂) frequencies and the carboxylate coordination are discussed, and UO₂(O₂CC₆F₅)₂(OAsPh₃)₂.0.40 (t-BuOH) is considered to have stereochemistry similar to that of the phosphine oxide complex. The complexes undergo decarboxylation in dimethyl sulphoxide yielding pentafluorobenzene and carbonatodioxouranium(VI) species not UO₂(C₆F₅)₂ derivatives.