α-Tris(2,4-pentanedionato-κ²O,O′)aluminium(III) at 240, 210, 180, 150 and 110 K: a new δ phase at 110 K

The crystal structures of trivalent metal acetylacetonate complexes can be grouped into several isomorphous series [an overview is given by Sabolović et al. (2004)]. According to an old nomenclature by Astbury & Gilbert (1926), the α polymorph crystallizes in the monoclinic crystal system with space group P2₁/c. The β and γ polymorphs crystallize in the orthorhombic crystal system with space groups Pbca and Pna2₁, respectively. Two different polymorphs of Al(acac)₃ (acac is acetylacetonate or 2,4-pentanedionate) have been previously investigated, namely the α and γ polymorphs. Both polymorphs can occur in the same crystallization batch. All previous crystallographic studies of the α polymorph were carried out at room temperature, according to a search of the Cambridge Structural Database (Version 5.28 of November 2006; Allen, 2002). Recently, we redetermined the crystal structure of the γ polymorph at 110 K, which contains four independent molecules (von Chrzanowski et al., 2006). In the course of our studies on Al(acac)₃, we have now redetermined the crystal structure of α-Al(acac)₃ by a multi-temperature measurement at 240, (Ia), 210, (Ib), 180, (Ic), 150, (Id), and 110 K, (Ie), in order to investigate the behaviour of atoms C11 and C15, which showed anomalous displacement parameters/disorder in the known studies of α polymorphs (Morosin, 1965; Diaz-Acosta et al., 2001; Fackler & Avdeef, 1974). At a temperature of 110 K, we found a new δ polymorph, (Ie), which is a superstructure of the α polymorph. The phase transition occurs between 150 and 110 K.

The transformation matrix from the high-temperature α polymorph to the low-temperature δ polymorph is (101/010/201). The determinant of this matrix is 3 and thus the volume is increased by a factor of three. The space group remains P2₁/c and the phase transition is therefore klassengleich. In the asymmetric unit of the δ polymorph there are three independent molecules (Fig. 1). All molecules have an approximate non crystallographic D₃ symmetry with r.m.s. deviations between 0.127 and 0.176 Å from ideal symmetry (Pilati & Forni, 1998). The molecules occupy pseudo-special positions with centers of gravity at (0.27, 0.23, 0.26), (0.40, 0.78, 0.07) and (0.06, 3/4, 0.40). All three molecules have essentially the same geometry as can be seen in a quaternion fit (Fig. 2a). This quaternion fit (Mackay, 1984) considers only the molecular structures, but does not take the crystal packing into account. The packing effects can be seen by the application of the transformation matrix to the α polymorph on the atomic coordinates of the δ polymorph. The result of this operation can be seen in Fig. 2(b). Two of the acac ligands have only very small deviations after this averaging, while the third ligand (C11x–C15x) is severely affected by the packing. The latter ligand corresponds to the ligand with large displacement parameters in the α polymorph. We therefore consider this phase transition as a disorder–order phase transition.

The ADDSYM routine of the program PLATON (Spek, 2003) indicates pseudo-translational symmetry for the δ polymorph. This pseudo-translational symmetry can also be seen in the X-ray intensities. Reflections with h + 2l = 3n correspond to the subcell and are much stronger than the other reflections. Nevertheless, the weak supercell reflections are clearly present and prevent a transformation to the subcell (Fig. 3). The strongest superstructure reflection is (220) with I/σ(I) of 157.29. The average I/σ(I) of the subcell reflections is 44.43, while the supercell reflections have an average I/σ(I) of 13.60. A test on pseudo-translational symmetry based on normalized structure factors from measured data (Cascarano et al., 1985) as implemented in the program SIR97 (Altomare et al., 1999) results in a value of 70% for the mean fractional scattering power of the electron density for reflections with h ± 1l = 3n and with h + 2l = 3n. The corresponding <E**2> value for these reflections is 2.409.

Despite the pseudo-translational symmetry, a full-matrix least-squares refinement with SHELXL97 (Sheldrick, 1997) can be performed with default refinement parameters and without restraints or constraints. No correlation matrix elements were larger than 0.5. The weighting scheme for the refinement was optimized by SHELXL97 based on all 11 232 unique reflections and results in a goodness-of-fit of 1.046. The corresponding goodness-of-fit for the 3741 strong subcell reflections without re-refinement and with the same weighting scheme is 1.418, and for the 7491 weak supercell reflections 0.881. Obviously, the weighted sigmas of the subcell reflections are underestimated and those of the supercell reflections overestimated in the refinement. A manual correction of the sigmas based on normal probability plots for subcell and supercell reflections did not change the outcome of the refinement.

The phase transition from the high-temperature α phase to the low-temperature δ phase breaks the translational symmetry for the C11–C15 acac ligand (see above). Nevertheless, the anisotropicity of some methyl groups is still rather large, but this now concerns also methyl groups of other acac ligands. Indeed, rigid-body analyses (Schomaker & Trueblood, 1998) for the three molecules result in relatively high agreement factors of R = 0.156–0.187 (R = {Σ[(U_obs - U_calc)²]/Σ(U_obs²)}^1/2). Difference plots (Hummel et al., 1990) between the observed displacement parameters and the rigid-body models (Fig. 4) make the large internal motions of the methyl groups visible. These internal motions are also reflected in a relatively large variation of the bond lengths. For example, the Al—O distances vary between 1.8704 (9) and 1.8924 (9) Å. The corresponding Al—O distances in the γ-polymorph (von Chrzanowski et al., 2006) are 1.8728 (13)–1.8947 (12) Å and show a similar variation. Because Al^III does not express Jahn–Teller distortions, this variation can only be explained by internal thermal motion. The thermal motion also explains why the Al—O distances of the crystal structure determinations are shorter than the 1.9159 Å obtained from quantum chemical calculations (Diaz-Acosta et al., 2001).

As expected, a temperature-dependent measurement of the α polymorph shows a decreasing thermal motion with decreasing temperature (Fig. 5). The eigenvalues of translation T_i and libration L_i tensors obtained from rigid-body analyses (PLATON; Spek, 2003) show that this decrease is linear (Fig. 6). In the whole temperature range, the agreement factors are rather high (R = 0.155–0.167). The corresponding internal motion is visualized by difference plots (Hummel et al., 1990) between the observed displacement parameters and the rigid-body models for (Ia)–(Id) (Fig. 7). The non-rigid behaviour is mainly expressed by only one acac ligand (C11–C15). This is the same ligand that breaks the translational symmetry in the δ phase. Quantum chemical calculations have proven the presence of out-of-plane deformations in isolated Al(acac)₃ molecules (Diaz-Acosta et al., 2001). However, from the observed phase transition we assume the anisotropicity of C11–C15 is a property of the crystal packing.