Bis[N-(2-hydroxy­ethyl)-β-alaninato]copper(II)

The title compound, [Cu(He-ala)₂], was synthesized as part of our systematic study of the coordination ability of dipodal ligands derived from β-alanine (Skorik et al., 2005, 2004, 2003, 2002). The acid–base and complexation equilibria of N-(2-hydroxyethyl)-β-alanine with Cu^II, Ni^II and Co^II have been studied by means of pH–potentiometric titration in aqueous media. Evidence was found for the presence of the [M(He-ala)] and [M(He-ala)₂] complexes (Uhlig & Linke, 1964). In the case of Cu^II ions, the monoprotonated [CuH(He-ala)] complex can also be formed in strong acidic conditions. To the best of our knowledge, no complexes of He-ala have previously been structurally characterized. In order to determine the Cu^II coordination geometry and the chelating pattern, the present X-ray crystal structure determination has been carried out on the title complex, (I), and the results are presented here.

The molecular structure of the [Cu(He-ala)₂] complex, along with the atomic numbering scheme, is shown in Fig. 1, while Table 1 lists selected bond lengths and angles. The structure of (I) consists of isolated [Cu(He-ala)₂] units, with the Cu^II ion located at the inversion centre in a square-bipyramidal geometry (4 + 2). The basal plane of the bipyramid is occupied by two N atoms of secondary amino groups and by two carboxylate O atoms, and the apices are occupied by two hydroxyl O atoms of two symmetrically arranged He-ala ligands. The axial Cu—O bonds are typically longer than the other in-plane bonds. The trans O—Cu—O or N—Cu—N angles are 180°, as required by symmetry. The cis angles involving the basal atom O2 differ only slightly from 90°, while the largest angular distortions of the octahedron occur for the N1—Cu1—O1 angles (Table 1).

Each monodeprotonated He-ala ligand binds to a Cu^II centre as a tridentate NO₂ ligand in a fac fashion by the formation of two chelate rings (one β-alaninate and one ethanolamine). There are three possible fac conformations for He-ala in a square-bipyramidal coordination, as shown in the scheme.

The isolated complex turned out to be a fac₁ isomer (Fig. 1). The selective formation of this isomer can be rationalized by reasoning that the most thermodynamically preferable isomer consists of the stronger field ligands in the equatorial positions and the weaker ligands in the apices of an axially elongated octahedron. Taking into account the spectrochemical series RNH₂ > RCOO⁻ > ROH (Bersuker, 1996), the fac₁ conformation for He-ala appears to be the most thermodynamically stable. For the same reason, a fac₁ isomer is favourable for the glycine derivative of ethanolamine (Ananeva et al., 1975; Ammar et al., 2001).

The six-membered β-alaninate chelate ring adopts a twist conformation, with atoms C5 and N1 not involved in the distortion of the initial planar hexagon. The puckering parameters (Cremer & Pople, 1975) generated by PLATON (Spek, 2003) are Q = 0.7335 (19) Å, θ = 94.75 (15)°, ϕ = 29.83 (15)°. The sum of the internal angles [675.0 (4)°] has a positive deviation from the ideal value, 648° = 120 + (109.5 × 4) + 90, and this exerts a stress, resulting in the flattening. The five-membered ethanolamine chelate ring adopts an envelope conformation, with atom C2 tilted by 0.646 (3) Å away from the Cu1/O1/C1/N1 plane; the puckering parameters are Q = 0.475 (2) Å and θ = 305.4 (2)°. The dihedral angle formed by the r.m.s. planes of the two chelate rings is 70.69 (9)°.

In the crystal structure of (I), the [Cu(He-ala)₂] molecules are involved in an extended two-dimensional system of hydrogen bonds, forming layers parallel to the (101) plane (Fig. 2a). Six intralayer molecules are hydrogen-bonded to the reference molecule; two of them form two N—H···O contacts each, while the other four form only O—H···O contacts (Table 2). The whole molecular packing may be represented as a superposition of these layers. Its topology was characterized with coordination sequences (O'Keeffe, 1995) calculated using the TOPOS4.0 professional program suite for crystallochemical analysis (Blatov et al., 2000). The molecular centres of gravity form the coordination sequence 12, 42, 92. In other words, the first, second and third coordination sphere of any molecule contains 12, 42 and 92 molecules, respectively. This sequence corresponds topologically to three-layered face-centred cubic (fcc) packing (O'Keeffe, 1995) which is slightly distorted geometrically. The simplified three-layered packing motif in the structure is shown in Fig. 2(b), where the centres of the molecules are represented as balls. Three molecules of the upper and lower layers and six molecules of the middle layer are shown. Thus, the hydrogen-bonded layers are joined by van der Waals interactions to the distorted fcc packing that is typical for molecular compounds (Kitaigorodskii, 1973; Peresypkina & Blatov, 2000; Braun & Huttner, 2005).