Effects of metal co-ordination geometry on self-assembly: a dinuclear double helicate complex and a tetranuclear cage complex of a new bis-bidentate bridging ligand

Citation
Rl. Paul et al., Effects of metal co-ordination geometry on self-assembly: a dinuclear double helicate complex and a tetranuclear cage complex of a new bis-bidentate bridging ligand, J CHEM S DA, (6), 2000, pp. 845-851
Citations number
36
Categorie Soggetti
Inorganic & Nuclear Chemistry
Journal title
JOURNAL OF THE CHEMICAL SOCIETY-DALTON TRANSACTIONS
ISSN journal
03009246 → ACNP
Issue
6
Year of publication
2000
Pages
845 - 851
Database
ISI
SICI code
0300-9246(2000):6<845:EOMCGO>2.0.ZU;2-3
Abstract
Reaction of 3-(2-pyridyl)pyrazole with 3,3'-bis(bromomethyl)biphenyl result ed in the new ligand L-1 which contains two bidentate chelating pyrazolyl/p yridine fragments separated by a meta-biphenyl spacer; this ligand is desig ned to act only as a bridging ligand, as the two bidentate sites are too fa r apart to co-ordinate to the same metal ion. The dinuclear copper(II) comp lex [Cu-2(L-1)(2)(OAc)(2)][BF4](2) is a double helicate in which each coppe r(II) centre is in a square pyramidal co-ordination geometry, arising from two bidentate pyrazolyl/pyridine groups (one from each ligand L-1) and a mo nodentate acetate. The structure is stabilised by extensive inter-ligand pi -stacking interactions. The complex [Ag-2(L-1)(2)][ClO4](2) is also assumed to be a double helicate. In contrast, reaction with Co-II afforded the tet ranuclear cage complex [Co-4(L-1)(6)][BF4](8), in which each bridging ligan d links two metal centres by spanning one edge of the Co-4 tetrahedron. Eac h metal is therefore in a pseudo-octahedral tris-chelate geometry, with the three bidentate chelating arms each coming from a different ligand L-1. Ag ain there is substantial inter-ligand stacking. Unlike other complexes with the same {M4L6} tetrahedral cage structure, the central cavity is not occu pied by a counter ion, showing that although the templating effect of a cou nter ion can be beneficial in the assembly of such cages it is clearly not essential. H-1 NMR spectroscopy suggests that there is a mixture of species in solution arising from other metal : ligand combinations; B-11 NMR spect roscopy shows that at -40 degrees C a [BF4](-) anion can become trapped in the cavity of the cage, giving a characteristic high-field resonance in add ition to that for the free [BF4](-) anions. Reaction of L-1 with Pd-II affo rded a mixture of products arising from ligand decomposition, of which [Pd- 2(L-1)(pypz)(2)][BF4][OH] was structurally characterised. It has a near-pla nar {Pd-2(mu-pypz)(2)}(2+) core [Hpypz = 3-(2-pyridyl)pyrazole, which has a risen from decomposition of L-1] with an additional bridging ligand L-1 co- ordinating in a 'basket-handle' mode, straddling the central core.