Mécanismes d'isomérisation et d'échange de ligand de complexes octaédriques labiles de cobalt (II)

There are only few structural thermodynamic and kinetic studies on labile octahedral complexes available today. Octahedral paramagnetic compounds of cobalt(II) have an optimum electronic relaxation leading to NMR spectra with good resolution. Therefore, they are excellent candidates to follow substitution and isomerisation processes by multinuclear NMR at variable pressure and temperature. This work groups the study of nine labile complexes (three families of compounds with three examples each) which can exist in different isomeric forms. The first part of the work concerns octahedral complexes with bis-chelating ligands of the general formula [Co(LA)2Rpy2] with LA being a bidentate acetylacetonate ligand and Rpy a monodentate ligand of the γ-substituted pyridine type. The second part of the work concerns octahedral complexes with tris-chelating ligands of the general [Co(LA)2(LB)] with LA being a bidentate acetylacetonate ligand and LB a bidentate ligand of the γ-substituted bipyridine type. The third part of the work concerns trinuclear heterometallic complexes with the general formula [Fe2M(μ3-O)(μ2-Ac)6(Rpy)3] with M = CoII, NiII and Rpy a monodentate ligand of the γ-substituted pyridine type. Each type of the metal centres has an octahedral geometry. For each example chosen, the different species present in equilibrium in solution have been identified and the thermodynamic and kinetic parameters measured are discussed. Mechanisms for isomerisation and ligand exchange are proposed on the basis of variable temperature and pressure kinetics data. It has been shown that the bis-chelate compounds isomerise via a dissociative mechanism (with an intermediate of bipyramid geometry). The monodentate ligand participates more or less depending on its donor character. In the case of complexes with γ-methylpyridine, the mechanism consists essentially of an opening of one arm of the bidentate ligand (with little exchange of the pyridine). However, in the case of complexes with γ-trifluoromethylpyridine, a more frequent exchange of the monodentate ligand is observed competing with the opening of the arm of the bidentate ligand. In the case of tris-chelate compounds the isomerisation mechanism proposed on the bases of the exchange matrix used for spectral simulations is a twist with an intermediate of prismatic geometry. This observed rates (faster) and the obtained activation parameters (smaller) are very different of those found for complexes with bis-chelating ligands. The trinuclear heterometallic complexes maintain their structure in dichloromethane solution. Variable pressure experiments allowed assigning a dissociative mechanism (D) for the exchange of pyridine on both the divalent and the trivalent centres. Experiments at variable temperature indicated an increase of lability for the trivalent metals and a decrease in lability for the divalent metals compared to the homoleptic octahedral mononuclear complexes. The activation parameters for the trinuclear heterometallic complexes are bigger than those found for the bis- and tris-chelate compounds.

Dimerization of Dendrimeric Lanthanide Complexes: Thermodynamic, Thermal, and Liquid-Crystalline Properties

Thomas Binderup Jensen, Kurt Schenk

A series of 10 different mesomorphic semidendrimeric tridentate ligands L5-L14 grafted with terminal cyanobiphenyl groups have been synthesized. Upon reaction with Ln(NO3)(3) (Ln = trivalent lanthanide), the central 2,6-bis(N-ethylbenzimidazol-2-yl)pyridine unit is meridionally tricoordinated to the metal to give rodlike monomeric [Ln(Lk)(NO3)(3)] and H-shaped dimeric [Ln(2)(Lk)(2)(NO3)(6)] complexes. For the small Lull' cation, the monomeric complexes are quantitatively formed in a noncoordinating CD2Cl2 solution, For larger cations (Ln = Eu, Pr), the thermodynamic equilibrium 2[Ln(Lk)(NO3)(3)] [Ln(2)(Lk)(2)(NO3)(6)] can be evidenced across the complete ligand series. Detailed thermodynamic studies show that the dimeric complexes result from the formation of primary intermetallic nitrate bridges whose strength depends on the metallic size. For each complex, secondary nonspecific interstrand van der Waals interactions produce nonartifactual enthalpy/entropy compensation. In the absence of solvent, only the complexes with the most extended ligands L5 and L6 produce thermotropic mesophases. Layered organizations are dominant (smectic A) with the induction of nematogenic behavior at high temperature when interstrand interactions are modulated by methyl substitutions. Correlations between the trend of dimerization and the sequences of thermotropic mesophases are attempted.

2010

Isomerization Mechanisms of Stereolabile tris- and bis-Bidentate Octahedral Cobalt(II) Complexes: X-ray Structure and Variable Temperature and Pressure NMR Kinetic Investigation

Lothar Helm, André Merbach, Fabrice Riblet, Rosario Scopelliti

The isomerization dynamics of five labile octahedral Co(II) compounds have been investigated by variable temperature and pressure 1H and 19F NMR spectroscopy in dichloromethane solution. The X-ray crystal structure of the two tris-chelates, [Co(HFA)2bpic] (1) and [Co(TTFA)2bpy] (2), show a distorted octahedral arrangement of the 4 oxygen and 2 nitrogen donor atoms, with bidentate ligand bite angles smaller than 90. On the other hand, in the three bis-chelates, trans(N)-Co(HFA)2(CH3py)2, cis(N)-cis(CF3)-trans(S)-Co(TTFA)2(CH3py)2, and trans(N)-trans(CF3)-Co(TTFA)2(CF3py)2, the replacement of the bidentate nitrogen donor ligands by two monodentate Rpy ligands leads to relaxed structures with almost regular octahedral arrangements of the donor atoms (HFA= 1,1,1,5,5,5-hexafluoro-2,4-pentanedionato anion; TTFA= 4,4,4-trifluoro-1-(2-thienyl)-1,3-butanedionato anion; bpy=2,20-bipyridine; bpic=4,40-dimethyl-2,20-bipyridine). In solution the five complexes are stereolabile and all possible isomers are formed: from one for 1 up to five for 4 and 5. All cis-N isomers form pairs of enantiomers, whereas the trans-N isomers are achiral. A solid state structure/isomerization mechanism/rate correlation has been established for the isomerization dynamics of these Co(II) tris- and bis-chelates. The two tris-chelate complexes 1 and 2, with a distorted octahedral solid state structure, show one and three isomers in solution and isomerize/tautomerize very rapidly according to Bailar twist mechanisms. The three bis-chelate complexes 3, 4, and 5, with a close to octahedral symmetry in the solid state, show two, five, and five isomers, respectively. They isomerize/tautomerize 3 orders of magnitude slower as the tris-chelates, by an intramolecular dissociative mechanism involving a ring-opening of an arm of a bidentate ligand to form a TBP intermediate with a dangling bidentate ligand. The results of this first systematic investigation of the isomerization mechanisms of highly labile Co(II) complexes are supported by the NMR observed exchange paths (up to five for complexes for 4 and 5), the variable temperature (185 to 312 K) and pressure (up to 200 MPa) activation parameters, and a detailed analysis of the solid state structures.

American Chemical Society2010

Low-dimensional supramolecular architectures at metal surfaces

Sebastian Stepanow

This thesis is concerned with supramolecular architectures assembled at metal surfaces. The investigations pursued two objectives. On the one hand, the focus was placed on the fabrication of low-dimensional surface-supported network structures by applying the concepts of conventional three-dimensional supramolecular chemistry at surfaces. Three main driving forces were explored for the construction of low-dimensional assemblies: hydrogen bonding, metal coordination and ionic interactions. The realized structures were characterized by scanning tunneling microscopy (STM) under ultra-high vacuum conditions. In particular, the interplay between the adsorbate-substrate coupling and lateral adsorbate interactions was addressed in the experiments. Further, the electronic and magnetic properties of the fabricated coordination structures were investigated. This characterization was done by x-ray absorption experiments at the synchrotron facility in Grenoble. Moreover, the response of the metal units and open cavity structures to the adsorption of large organic and small gas molecules was studied by temperature controlled STM experiments. The first part of the thesis deals with hydrogen bonded supramolecular assemblies. Simple aromatic carboxylic acids were employed to study the assembly principles and in particular effects arising from the substrate and molecular structure. The investigation of TPA (1,4-benzenedicarboxylic acid) adlayers on Cu(100) at different substrate temperatures revealed how the protonation status of the carboxyl moieties affects the topology of the assemblies. Further, the influence of the molecular backbone functionality and symmetry is addressed in comparative investigations on TPA and PDA (2,5-pyrazinedicarboxylic acid) as well as BDA (4,4'-biphenyldicarboxylic acid) and SDA (4',4" trans-ethene-l,2-diyl-bisbenzoic acid) adlayers on Cu(100). In the second part of the thesis, metal-ligand interactions were employed for the construction of supramolecular architectures at a Cu(100) surface. The concepts of conventional coordination chemistry were successfully applied at the surface. Iron atoms in conjunction with rod-like aromatic molecular linkers comprising carboxyl, pyridyl and hydroxyl functional groups assemble into a rich variety of open network structures with distinctly arranged mono- and diiron coordination centers and well-defined cavities. The results show that the adsorbate-substrate coupling considerably affects the local coordination environment of the iron units when the molecular backbone length is varied. The occurrence of structural isomerism in open network structures is addressed in a comparative study of heterofunctional and homofunctional linker molecules. It is shown that the former ligand allows only one topologically pure structure while the other linker forms two phases with different topology. The hydroxyl ligand has been used to construct distorted hexagonal coordination networks containing threefold coordinated single iron atoms. The comparison between the networks on Cu(100) and Ag(111) surfaces shows marked differences, which are attributed to adsorbate-substrate interactions. Finally, a novel design strategy for the fabrication of two-dimensional coordination structures at surfaces is introduced by using alkali metal ions in conjunction with carboxylate ligands. The interaction between the components is dominated by electrostatic forces and is of intermediate bond strength as in the case of hydrogen bonding and transition metal coordination. It is expected, that substrate symmetry and registry plays a larger role in the network formation, because the ionic interaction is not directional. The chemical as well as magnetic properties of the fabricated coordination networks are examined in the last part of the thesis. The adsorption of C60 molecules on open network structures reveals how cavity size and chemical functionality affect the bond strength to the guest molecules as well as the number of accommodated C60 molecules. Since transition metal clusters, and in particular diiron units, are the catalytic active centers in various proteins, the reactivity of various mono- and diiron coordination structures to molecular oxygen was investigated in temperature controlled STM experiments. In particular, the focus was placed on the structural relaxation upon gas adsorption and chemical reaction. At last, the magnetic properties of the metal coordination centers are addressed in XMCD experiments. The iron units are found to be paramagnetic at temperatures down to 5 K and show distinct magnetic anisotropy and magnetization loops. These experiments demonstrate that surface-supported metal coordination structures are a promising class of materials for applications in the field of heterogenous catalysis and surface magnetism.