Al₆Ti₂O₁₃, a new phase in the Al₂O₃-TiO₂ system

The structural examination of the titanium suboxides with the general formula Ti_nO_2n-p (where n and p are positive integers) led to the evolution of the principle of crystallographic shear as an underlying structural principle (Hyde & Andersson, 1989). This concept is devoted to the question of how structures with similar stoichiometry are related (Gibb & Anderson, 1972b). After the validation of this concept for titanium oxides by means of transmission electron microscopy (TEM) and single-crystal X-ray diffraction, the investigations were extended to pseudo-binary systems, M₂O₃–TiO₂, where M₂O₃ denotes an oxide of a trivalent cation with an ionic radius similar to Ti⁴⁺, e.g. Cr³⁺ (Bursill et al., 1971; Gibb & Anderson, 1972a) and Fe³⁺ (Gibb & Anderson, 1972b).

Nevertheless, relatively little attention has been paid to the phase system Al₂O₃–TiO₂, in which only one compound is known, namely β-Al₂TiO₅, which adopts the pseudobrookite (Pauling, 1930) structure type (Austin & Schwartz, 1953). This compound has been studied extensively because of its physical properties. As a result of the low thermal expansion (Bayer, 1971, and references cited therein), it has, for instance, found a number of commercial applications with major European motor manufacturers as exhaust port liners in both petrol and diesel engines as a means of improving thermal efficiency. It is also under serious consideration for use in exhaust manifold inserts, piston crowns and turbocharger liners. Additionally, it finds application in non-ferrous metallurgical industries (Thomas & Stevens, 1989). Later TEM investigations of Al₂O₃–TiO₂ samples with 50 to 70 mol% Al₂O₃ (Mazerolles et al.,1994) revealed new phases with c axes of 12.4 and 16.8 Å, respectively, that were deemed by electron diffraction patterns to be structurally related to β-Al₂TiO₅.

Our research interest regarding high refractory oxides (Kamiya et al., 1980; Yashima et al., 1993) led us to the reinvestigation of the Al₂O₃–TiO₂ system using an arc-imaging furnace. This method of preparation ensures the complete melting of the oxides, avoiding the diffusion problems often observed in solid-state reactions, as well as reactions with the crucible material. In the course of these experiments, we were able to synthesize homogenous samples of the title novel compound suitable for single-crystal X-ray diffraction. The stoichiometry of the investigated sample was confirmed to be Al₆Ti₂O₁₃, as indicated from an energy-dispersive X-ray diffraction study of multiple crystalline fragments.

The structure of the title compound was solved and refined in space group Cm2m. There are five crystallographically independent metal (M) atomic sites and eight such O atomic sites in the unit cell. Three of the M sites have point symmetry m, while the other two have point symmetry m2m. One of the M sites with point symmetry m2m is situated in a trigonal bipyramid of O atoms. The population refinement indicated that this site is wholly occupied by Al. This site is named Al1. The remaining M sites, named M2, M3, M4 and M5, are all located in distorted oxygen octahedra and are populated with both Ti and Al, in the ratio of 2/7 Ti and 5/7 A l.

It should be noted that the refinement of the occupancies of the M2–M5 sites individually gave results that were either within experimental error of the 2/7 Ti: 5/7 A l ratio, or were so highly correlated with the displacement parameters as to be unreliable. Consequently, it was decided to fix the occupancies of these sites to be the same. Small variations from this Ti:Al ratio among the different sites cannot be ruled out.

The rather high residual electron density prompted us to carry out a thorough examination of all electron-density features (especially near the highest peaks). The residual electron density displayed in Fig. 1(a) illustrates typical electron features found on the mirror planes, while the rest of the structural model is relatively free from any residual electron density, e.g. Fig. 1(b). The 2.8 (2) e Å⁻³ peak located 0.709 (8) Å from atom O4 is the most pronounced peak, while another electron-density peak of 2.5 (2) e Å⁻³ is positioned 0.4993 (2) Å from the Al1 site. The electron-density holes follow the same patterns as the peaks, with the largest hole of −2.3 (2) e Å⁻³ located 0.455 (5) Å from the M2 site.

It is not totally unexpected to find some rather high peaks of residual electron density, as Al₆Ti₂O₁₃ samples in general should be likely to contain intergrowths of related compounds. High-resolution TEM studies of Al-enriched β-Al₂TiO₅ crystals (Mazerolles et al.,1994) showed intergrowth between β-Al₂TiO₅, the present Al₆Ti₂O₁₃ and still another phase of unknown composition. This was indicated as an observation of two unknown materials with c axes of 12.4 Å and 16.8 Å, respectively. The former probably corresponds to the structure analysed in the present study. The latter may correspond to an as yet unknown structure with an Al-richer composition. It is therefore possible that a small amount of intergrowth with β-Al₂TiO₅ and/or the still unknown Al-richer compound is present in the crystal studied here.

The arrangement of atoms in the new structure, Al₆Ti₂O₁₃, is shown in Fig. 2. Viewing the atomic lattice along the c axis reveals layers of atoms which are separated by b/2, and each layer is further divided into infinite double strings consisting of metal and O atoms, as seen in Fig. 3. These double strings can be regarded as the equatorial plane of a double chain of polyhedra of the same height, as shown in Fig. 4. Four different types of distorted octahedra and one type of trigonal bipyramid are connected by common edges and apices. The centres of all four octahedra are occupied by both Al³⁺ and Ti⁴⁺ ions, whereas the trigonal bipyramid is exclusively centred by Al³⁺ ions (the Al1 site). The M—O distances within the octahedra range between 1.790 (8) (M4—O7) and 2.093 (8) Å (M3—O6), while they range more tightly between 1.789 (8) (Al1—O1) and 1.936 (6) Å (Al1—O3) for the trigonal bipyramid.

For each octahedron, the shortest M—O distance is found for the O atoms which lie inside the double chain (Fig. 2; atoms O1, O4 and O7). These belong to only three adjacent polyhedra, whereas all other O atoms connect to four. With the exception of the octahedron formed by M2, the next shortest distances are found for the apical atoms (Fig. 2; atoms O3, O5, O6 and O8). Furthermore, all the octahedra in the double strings share edges with the nearest neighbouring octahedra, forming an edge-sharing chain [–M2O₆—M4O₆—M3O₆—M5O₆—M3O₆—M4O₆—M2O₆–] of octahedra. The shortest M—M distance is 2.839 (6) Å and this is located between M3 and M4, sharing an octahedral edge formed by O4 and O7. The shortest O—O distance of 2.449 (9) Å is found between O4 and O7.

The whole Al₆Ti₂O₁₃ structure can be built up by the above-described double chains, as shown in Fig. 4, with the layers sharing polyhedra edges as well. Channels along [100] and [010] result, whereas layers of condensed polyhedra are formed parallel to <010>. However, it should be noted that all polyhedra are strongly distorted. The bonding angle found in the equatorial plane of the trigonal bipyramid is either 127.8 (2) or 104.4 (3)°, which are far from the ideal 120°. The distorted nature of the octahedra is easily described by the divergence from the ideal 90 and 180° bonding angles found in a perfect octahedron. The ideally 90° bond angles in the M2O₆ octahedron vary between 78.0 (2) and 103.2 (2)°, while the vertical O3^iv—M2—O3^v angle is 142.3 (4)°, which is far from 180° [symmetry codes: (iv) 1/2 + x, 1/2 + y, z; (v) −1/2 + x, 1/2 + y, z]. Analogous distortion is seen in all other polyhedra, as well as in the similar compound β-Al₂TiO₅ (Morosin & Lynch, 1972).

Among the octahedra, we find an AlO₅ trigonal bipyramid, which is a less common coordination for Al in crystalline oxides (Santamaria-Perez & Vegas, 2003). A quick review of all Al-containing structures reported to the Inorganic Crystal Structure Database (ICSD, 2001) shows that about 4% have one or more crystallographically independent atomic sites, partly or fully occupied by Al, coordinated to five O atoms. One of the most commonly investigated structure types with AlO₅ polyhedra is the magnetoplumbite structure (Adelsköld, 1938), e.g. SrO(Al₂O₃)₆ (Lindop et al., 1975) and CaO(Al₂O₃)₃(Fe₂O₃)₃ (Harder & Müller-Buschbaum, 1977), with the latter having mixed Al/Fe occupancies on all metal sites. Other examples of five-coordinated Al can be found in the families of aluminosilicates, for instance kyanite (Norton, 1925; Burnham, 1963) and andalusite (Taylor, 1929; Burnham & Buerger, 1961), which both are polymorphs of Al₂SiO₅. Recent studies have revealed that AlO₅ units are also present in amorphous alumina (Gutierrez & Johansson, 2002), as well as in liquid alumina (Landron et al., 2001).

Al and Ti have a tendency to share atomic sites, as the atomic radii of Al³⁺ and Ti⁴⁺ (53 and 61 pm, respectively; Shannon, 1976) are alike enough to facilitate site sharing in oxide structures. Thus, it is not unexpected that no apparent ordering exists for the crystallographically independent octahedra centres. Similar disorder has, for instance, been seen in studies of β-Al₂TiO₅ (Morosin & Lynch, 1972; Epicier et al., 1991) which, like Al₆Ti₂O₁₃, is composed of strongly distorted octahedra. However, the trigonal bipyramid is, in contrast with the octahedra, exclusively occupied by Al according to the present X-ray single-crystal structure analysis. A similar situation was found in the compound SrFe₇Al₅O₁₉, where cation ordering happens in such a way that the bipyramids are exclusively centred by Al³⁺ (Pausch & Müller-Buschbaum, 1976).