1. Chemical context

Metallacrowns, first recognized in 1989 by Pecoraro (Pecoraro, 1989), belong to a class of mol­ecules known as metalla­macrocycles that also include, but are not limited to, metalla­helices and metallahelicates (Kramer et al., 1993; Piguet et al., 1997), metallacryptands and metallacryptates (Ma et al., 1980; Saalfrank et al., 1988; Zaleski et al., 2005), and metallic wheels and rings (Taft et al., 1994; Müller et al., 1995; Murrie et al., 1999). The archetypal metallacrown (MC) framework is based on a cyclic metal–nitro­gen–oxygen repeat unit similar to the crown ether cyclic carbon–carbon–oxygen repeat unit. Since their inception metallacrowns have been considered not only structural analogues of crown ethers, but also functional analogues, as metallacrowns typically bind a metal ion in the central cavity. In addition, as cryptands can be considered the three-dimensional analogues of crown ethers (Lehn, 1978), metallacryptands with an M–N–O repeat unit (Fig. 1) can be considered the three-dimensional analogues of metallacrowns (Lutter et al., 2018). Metallacrown and metallacryptate chemistry has mainly focused on incorporating transition metal ions in the ring repeating unit as these ions impart inter­esting magnetic and spectroscopic properties. The use of main-group metal ions has mainly been limited to gallium (Lah et al., 1993; Jiang et al., 2019; Athanasopoulou et al., 2019), tellurium (Kübel et al., 2010; Ho et al., 2016; Ho et al., 2017; Ho et al., 2019; Wang et al., 2019), and tin (Zhao et al., 2010a; Zhao et al., 2010b). Recently though, gallium-based metallacrowns and metallacryptates have gained renewed inter­est as potential optical imaging agents (Chow et al., 2016; Nguyen et al., 2018; Lutter et al., 2018, 2019, 2020).

Figure 1 Schematic comparing the [3.3.1] metallacryptand of 1 and 2 to a [3.3.1] cryptand.

For many metallacrowns and metallacryptates, a common ligand is salicyl­hydroxamic acid (H₃shi), which can be triply deprotonated to produce salicyl­hydroximate (shi³⁻), and when this ligand set is combined with transition-metal ions in a 3+ oxidation state, a plethora of structural arrangements is possible (Mezei et al., 2007). In addition, one hallmark of MC chemistry is the ability to easily substitute components of the complexes and still generate similar structures. For instance, in a series of Ln^III[12-MC_shi-4] structures with ring manganese(III) ions, the Mn^III ions can be substituted with gallium(III) to generate comparable 12-MC-4 structures (Chow et al., 2016). Thus, a logical extension would be to include aluminum(III) into the MC ring, as this would maintain the charge balance of the overall complexes. However, to date aluminum has not been used to generate either an archetypal metallacrown or metallacryptand complex. Herein we present two [3.3.1] metallacryptate complexes [DyAl₆Na₅(OAc)(Hshi)₂(shi)₇(DMF)₈]·H₂O·4DMF, 1, and [DyAl₆Na₅(OAc)(Hshi)₂(shi)₇(DMF)_8.5]₂·6.335DMF, 2, where DMF is N,N-di­methyl­formamide. Complexes 1 and 2 represent the first metallacrowns or metallacryptates to contain aluminum as a ring metal. Future studies will focus on the luminescent and magnetic properties of these and related compounds, as the aluminum ions do not quench the luminescence of the Ln^III ions and the diamagnetic nature of the aluminum ions generates a potential single-ion magnet with the paramagnetic lanthanide ion at the center of the mol­ecule.

2. Structural commentary

The two-dimensional structures of the metallacryptates of 1 and 2 are very similar; however, there are key structural differences. Both compounds are synthesized in the same manner with a 1:16:16:32 ratio between the reactants, Dy(NO₃)₃: Al(OAc)₂OH: H₃shi: NaOAc; however, the crystals have different space groups (Cc for 1 and Pc for 2). At this time it is not clear what factors induce the crystallization of 1 or 2. In 1 there is only one type of metallacryptate in the two-dimensional network (Fig. 2), while in 2 there are two different but very similar metallacryptates. Compound 2 can be considered a dimeric unit of two metallacryptates (Fig. 3). When it is necessary to distinguish the two metallacryptates for 2, the designations 2A (associated with Dy1) and 2B (associated with Dy2) will be used. Each metallacryptate is connected to its nearest neighbors to generate a two-dimensional sheet (Figs. 4 and 5), which will be described in greater detail below. The individual repeat unit of the two-dimensional network is akin to a metallacrown but can more accurately be described as a metallacryptate. As a cryptand is considered a three-dimensional analogue to a crown ether, the aluminum-based shells of 1 and 2 can be considered as three-dimensional metallacrowns, thus as metallacryptands (Fig. 6a). Furthermore, upon binding a metal ion in the central cavity, a cryptand is transformed into a cryptate. Compounds 1 and 2 bind a Dy^III ion in the central cavity to produce a metallacryptate (Figs. 6b and 7). Each metallacryptate unit consists of one Dy^III ion, six Al^III ions, and five Na⁺ ions to provide a total charge of 26+, which is counterbalanced by one acetate, seven triply deprotonated shi³⁻ ligands, and two Hshi²⁻ ligands with a total charge of 26-. For the Hshi²⁻ ligands, the phenolate and oxime oxygen atoms are deprotonated, while the oxime nitro­gen atom remains protonated and does not coordinate to any metal ions. Beyond overall mol­ecular charge considerations, the oxidation state assignments of the Dy^III and Al^III ions are also confirmed by bond-valence-sum (BVS) values (Table 1) (Brese & O'Keeffe, 1991; Trzesowska et al., 2004). The Na⁺ ions do not participate in the metallacryptate structure, but serve to connect neighboring mol­ecules in a two-dimensional sheet.

Figure 2 The single-crystal X-ray structure of [DyAl6Na5(OAc)(Hshi)2(shi)7(DMF)8]·H2O·4DMF, 1, including connections to neighboring sodium ions [symmetry codes: (i) x − , y − , z; (ii) x + , y + , z; (iii) x − , y + , z; (iv) x + , y − , z]. The displacement ellipsoids are at the 50% probability level. For clarity, labels have only been added to the metal ions and some of the carbon, nitro­gen, and oxygen atoms. In addition, the solvent water and DMF mol­ecules, the hydrogen atoms, and disorder have been omitted. Color scheme: green – Al, yellow – Dy, light blue – Na, red – oxygen, dark blue – nitro­gen, and gray – carbon. All figures were generated with the program Mercury (Macrae et al., 2020).

Figure 3 The single-crystal X-ray structure of [DyAl6Na5(OAc)(Hshi)2(shi)7(DMF)8.5]2·6.335DMF, 2, including connections to neighboring sodium ions [symmetry codes: (i) x, y − 1, z; (ii) x, y + 1, z; (iii) x + 1, y, z; (iv) x − 1, y, z]. The displacement ellipsoids are at the 50% probability level. For clarity, labels have only been added to the metal ions and some of the carbon, nitro­gen, and oxygen atoms. In addition, the solvent DMF mol­ecules, the hydrogen atoms, and disorder have been omitted. See Fig. 2 for additional display details.

Figure 4 The two-dimensional network of 1 generated by the bridging Na+ ions between the metallacryptate units. Each metallacryptate is connected to four adjacent metallacryptates. The view is along the c axis of the unit cell. See Fig. 2 for additional display details.

Figure 5 The two-dimensional network of 2 generated by the bridging Na+ ions between the dimeric metallacryptate units. Each metallacryptate is connected to four adjacent dimeric metallacryptates. The view is along the c axis of the unit cell. See Fig. 2 for additional display details.

Figure 6 The (a) metallacryptand and (b) metallacryptate views of 1 highlighting the [3.3.1] connectivity between the metal ions. See Fig. 2 for additional display details.

Figure 7 The metallacryptate views of (a) 2A and (b) 2B demonstrating that the two metallacryptates of the dimeric unit are enanti­omers. See Fig. 2 for additional display details.

The metallacryptand structure can best be described as a [3.3.1] complex based on the similar [3.3.1] cryptand (Krakowiak et al., 1993), where the numbers indicate the number of oxygen atoms in each linkage of the metallacryptand (Fig. 1). In the metallacryptand, two Al^III ions serve as the anchor points of the structure, akin to the nitro­gen atoms of a cryptand (Fig. 1 & 6). There are two linkages between the anchor Al^III ions consisting of an O–N–Al–O–N–Al–O–N pattern and one shorter linkage with an N–O pattern, thus the [3.3.1] nomenclature. This metal–nitro­gen–oxygen repeating pattern is that of the archetypal metallacrown; thus, these structures can be considered three-dimensional metallacrowns. The repeating units of the metallacryptand strands are generated from the seven shi³⁻ ligands with the hydroximate group of the ligand providing the N–O linkage. The oxime oxygen atoms of the linkages bind a Dy^III ion in the central cavity to generate the metallacryptate. The two remaining Hshi²⁻ ligands are not involved in the metallacryptand structure but instead bind on the periphery of the structure and provide two additional oxime oxygen atoms to complete the coordination of the Dy^III ion and serve as bridging ligands to the Al^III ions; however, the Hshi²⁻ ligands do not provide an N–O repeat unit in the structure between the metal ions as the nitro­gen atoms remain protonated, thus negating their participation in the metallacryptand linkages.

Each Dy^III is nine-coordinate with nine oxime oxygen atoms providing the coordination sphere. As stated above, seven of the oxime oxygen atoms are provided by the seven shi³⁻ ligands, which participate in the formation of the metallacryptand and form bridges to all six Al^III ions. The two remaining oxime oxygen atoms are provided by the two Hshi²⁻ ligands. Each oxime oxygen atom of the Hshi²⁻ ligands also serves as a one atom μ₃-bridge between the Dy^III ion, one Al^III ion, and one Na⁺ ion. A SHAPE (SHAPE 2.1; Llunell et al., 2013) analysis of the Dy^III geometry (Table 2; Fig. 8) yields the lowest continuous shape measure (CShM) value for a spherical capped square anti­prism (1.212 for 1, 1.305 for 2A, and 1.225 for 2B); however, comparable CShM values are obtained for a spherical tricapped trigonal prism (1.370 for 1, 1.640 for 2A, and 1.521 for 2B) and muffin (1.728 for 1, 1.813 for 2A, and 1.803 for 2B) geometries (Llunell et al., 2013; Pinsky & Avnir, 1998; Cirera et al., 2005). A muffin geometry can best be described as a configuration with a trigonal base, a penta­gonal equatorial plane, and a single point vertex (Ruiz-Martínez et al., 2008).

Figure 8 Polyhedral views of the coordination geometry for Dy1 of 1: (a) spherical capped square anti­prism; (b) spherical tricapped trigonal prism; (c) muffin. See Fig. 2 for additional display details.

There are six Al^III ions per metallacryptate; two of the Al^III ions are five coordinate while the remaining four are six coordinate (Figs. 9–11). For the five-coordinate Al^III ions, the geometries are either trigonal bipyramidal or spherical square pyramidal. For Al1 and Al6 of 1, the CShM values (Table 3) slightly favor a trigonal–bipyramid geometry over a spherical square pyramid (1.533 vs 1.880 for Al1 and 1.220 vs 1.797 for Al6). For 2, Al3 is clearly trigonal pyramidal with a CShM value below 1.0 (CShM = 0.874), where a value less than 1.0 typically indicates only minor distortions from the ideal shape (Cirera et al., 2005). However, the remaining Al^III ions, Al4, Al8, and Al10, are spherical square pyramidal with CShM values of 1.168, 0.540, and 1.324, respectively, though for Al10 the CShM value for a trigonal bipyramid is 1.759, indicating the geometry is between the two ideal scenarios. For all of the five-coordinate Al^III ions of 1 and 2, the coordination environment is composed of two chelate rings, a five-membered ring formed from the oxime oxygen and carboxyl­ate oxygen atoms of one shi³⁻ and a six-membered ring formed from the oxime nitro­gen and phenolate oxygen atoms of a second shi³⁻ ligand. The coordination is completed by a phenolate oxygen atom of a Hshi²⁻ ligand. For the six-coordinate Al^III ions (Al2–Al5 for 1 and Al1, Al2, Al5, Al6, Al7, Al9, Al11, Al12 for 2) the geometries are clearly octa­hedral with all CShM values below 2.0 (Table 4). All of the six-coordinate Al^III ions adopt a propeller configuration with two Δ and two Λ stereoconfigurations per metallacryptate. For Al2 of 1, the Δ stereoconfiguration is composed of three cis chelate rings: one five-membered chelate ring formed by the oxime and carboxyl­ate oxygen atoms of a shi³⁻ ligand, one five-membered chelate ring formed by the oxime and carboxyl­ate oxygen atoms of an Hshi²⁻ ligand, and a six-membered chelate ring formed from the oxime nitro­gen and phenolate oxygen atoms of another shi³⁻ ligand. For Al4, the Δ stereoconfiguration has three chelate rings: two five-membered chelate rings and one six-membered chelate ring from three different shi³⁻ ligands. For Al3, the Λ configuration consists of three cis chelate rings: one five-membered ring and two six-membered rings from three shi³⁻ ligands. For Al5, the Λ stereoconfiguration is formed by cis five- and six-membered chelate rings of two shi³⁻ ligands and two cis oxygen atoms, a μ-carboxyl­ate oxygen atom of an acetate anion and the oxime oxygen atom of an Hshi²⁻ ligand. The μ-carboxyl­ate atom of the acetate anion connects Al5 to Na5. For 2A, the Δ and Λ Al^III ions (Δ: Al1 and Al5; Λ: Al2 and Al6) have the same coordination environment as their Al^III ions counterparts in 1; however, for 2B, the Δ and Λ environments are reversed relative to 1 and 2A (Figs. 9–11). The Λ stereoconfiguration of Al7 has three cis chelate rings: one five-membered ring of a shi³⁻ ligand, one five-membered ring of an Hshi²⁻ ligand, and one six-membered ring of a shi³⁻ ligand. The Λ stereoconfiguration of Al12 has cis chelate rings from three shi³⁻ ligands (two five-membered rings and one six-membered ring), while the Δ stereoconfiguration of Al9 has cis chelate rings from three shi³⁻ ligands (one five-membered ring and two six-membered rings). For Al11, the Δ stereoconfiguration is completed by cis five- and six-membered chelate rings of two shi³⁻ ligands and two cis oxygen atoms, a μ-carboxyl­ate oxygen atom of an acetate anion and the oxime oxygen atom of an Hshi²⁻ ligand. Thus, the metallacryptand portions of 2A and 2B can be considered enanti­omers (Fig. 7).

Figure 9 Coordination geometries for the AlIII ions of 1: (a) Al1 – trigonal pyramidal; (b) Al2 – octa­hedral, Δ; (c) Al3 – octa­hedral, Λ; (d) Al4 – octa­hedral, Δ; (e) Al5 – octa­hedral, Λ; (f) Al6 – trigonal pyramidal. See Fig. 2 for additional display details.

Figure 10 Coordination geometries for the AlIII ions of 2A: (a) Al1 – octa­hedral, Δ; (b) Al2 – octa­hedral, Λ; (c) Al3 – trigonal pyramidal; (d) Al4 – spherical square pyramidal; (e) Al5 – octa­hedral, Δ; (f) Al6 – octa­hedral, Λ. See Fig. 2 for additional display details.

Figure 11 Coordination geometries for the AlIII ions of 2B: (a) Al7 – octa­hedral, Λ; (b) Al8 – spherical square pyramidal; (c) Al9 – octa­hedral, Δ; (d) Al10 – spherical square pyramidal; (e) Al11 – octa­hedral, Δ; (f) Al12 – octa­hedral, Λ. See Fig. 2 for additional display details.

The Na⁺ ions of 1 and 2 are either five- or six-coordinate. The SHAPE analysis indicates that the geometries are severely distorted in each case with the CShM values typically above 3.0, which can be considered an upper threshold value where below 3.0 is still considered an adequate description of the geometry though there are significant distortions (Cirera et al., 2005). For the five-coordinate Na⁺ ions (Na4 of 1, and Na4 and Na7 of 2), Na4 of 1 can best be described as a spherical square pyramid, while for Na4 and Na7 of 2, the geometry can best be described as trigonal bipyramidal (Table 5). The coordination environment of each Na⁺ ion is the same and consists of a five-membered chelate ring from the carboxyl­ate oxygen and oxime oxygen atoms of an Hshi²⁻ ligand, an oxime oxygen atom of a different Hshi²⁻ ligand, a carboxyl­ate oxygen atom of an acetate ion, and a carbonyl oxygen atom of a DMF mol­ecule. In addition to the Al^III propeller stereoconfigurations described above, the differences between 1 and 2 stem from the acetate anions and DMF mol­ecules of the five-coordinate Na⁺ ions. In 1, the acetate anion forms a three-atom bridge to a neighboring Na⁺ ion (Na5) and the acetate anion does not connect to a neighboring metallacryptate. In 2, the acetate anions not only form a three-atom bridge to a neighboring Na⁺ of the same metallacryptate (Na4 to Na5 of 2A and Na7 to Na6 of 2B), but also form μ-oxygen bridges to an Na⁺ ion of a neighboring metallacryptate unit (Na4 to Na6 and Na7 to Na5). In addition, the DMF mol­ecules of Na4 of 1 and Na7 of 2B bind in a terminal fashion; however, for Na4 of 2A the carbonyl oxygen atom of the DMF forms a μ-bridge between Na4 and Na6, which contributes to the linkage between 2A and 2B. Overall the connections between Na4, Na5, Na6, and Na7 of 2 connect the two metallacryptates to form a dimeric unit.

For the six-coordinate Na⁺ ions, the geometries can best be described as severely distorted octa­hedra with most CShM values above 3.0 and an average value of 3.591 for 1 and 4.039 for 2 (Table 6). For both 1 and 2, the six-coordinate Na⁺ ions serve as connection points between neighboring metallacryptate units and this connectivity generates the two-dimensional sheet. A description of the coordination environment of Na1–Na3 and Na5 of 1 and the connectivity to neighboring metallacryptates follows. For Na1, the coordination environment consists of three μ-carbonyl oxygen atoms of three different bridging DMF mol­ecules, a carbonyl oxygen atom of a terminal DMF mol­ecule, a phenolate oxygen atom of a shi³⁻ ligand, and a carboxyl­ate oxygen atom of a different shi³⁻ ligand. The three bridging DMF mol­ecules connect Na1 to the Na3 ion of a neighboring metallacryptate. For Na2, the coordination environment consists of three μ-carbonyl oxygen atoms of bridging DMF mol­ecules, two phenolate oxygen atoms of two different shi³⁻ ligands, and a carboxyl­ate oxygen atom of a third shi³⁻ ligand. The three bridging DMF mol­ecules connect Na2 to the Na5 ion of a neighboring metallacryptate. For Na3, the coordination environment consists of three μ-carbonyl oxygen atoms of bridging DMF mol­ecules, two carboxyl­ate oxygen atoms of two different shi³⁻ ligands, and a phenolate oxygen atom of a third shi³⁻ ligand. The three bridging DMF mol­ecules connect Na3 to the Na1 ion of a neighboring metallacryptate. For Na5, the coordination environment consists of three μ-carbonyl oxygen atoms of bridging DMF mol­ecules, a carboxyl­ate oxygen atom of an acetate anion that bridges between Na5 and Al5, a phenolate oxygen atom of a shi³⁻ ligand, and a carboxyl­ate oxygen atom of an Hshi²⁻ ligand. The three bridging DMF mol­ecules connect Na5 to the Na2 ion of a neighboring metallacryptate. The series of μ-bridging DMF mol­ecules between the peripheral Na⁺ ions of the metallacryptates generate the two-dimensional network of the compound (Fig. 4). If the shape of the metallacryptate of 1 is approximated as a square, then the Na⁺ ions Na1, Na2, Na3, and Na5 lie at each corner. Each Na⁺ ion connects to one adjacent MC via three μ-carbonyl oxygens of the bridging DMF mol­ecules. Thus, each metallacryptate unit is connected to four adjacent metallacryptates via the peripheral Na–DMF–Na connections and a two-dimensional sheet of metallacryptates is generated (Na1 to an adjacent Na3, Na2 to an adjacent Na5, Na3 to an adjacent Na1, and Na5 to an adjacent Na2).

A description of the coordination environment of Na1–Na3, Na5, Na6, and Na8–Na10 of 2 and the connectivity to neighboring metallacryptates follows. For Na1, the coordination environment consists of two μ-carbonyl oxygen atoms of two different bridging DMF mol­ecules, a carbonyl oxygen atom of a terminal DMF mol­ecule, two phenolate oxygen atoms of two different shi³⁻ ligands, and a carboxyl­ate oxygen atom of a third shi³⁻ ligand. The two bridging DMF mol­ecules connect Na1 to the Na10 ion of a neighboring metallacryptate. For Na2, the coordination environment consists of three μ-carbonyl oxygen atoms of bridging DMF mol­ecules, a carbonyl oxygen atom of a terminal DMF mol­ecule, a phenolate oxygen atom of a shi³⁻ ligand, and a carboxyl­ate oxygen atom of a different shi³⁻ ligand. The three bridging DMF mol­ecules connect Na2 to the Na3 ion of a neighboring metallacryptate. For Na3, the coordination environment consists of three μ-carbonyl oxygen atoms of bridging DMF mol­ecules, a carboxyl­ate oxygen atom of a shi³⁻ ligand, a phenolate oxygen atom of a different shi³⁻ ligand, and a carboxyl­ate oxygen atom of an Hshi²⁻ ligand. The three bridging DMF mol­ecules connect Na3 to the Na2 ion of a neighboring metallacryptate. For Na5, the coordination environment consists of two carbonyl oxygen atoms of terminal DMF mol­ecules, a carboxyl­ate oxygen atom of an acetate anion that bridges between Na5 and Al2, a carboxyl­ate oxygen atom of a different acetate anion that bridges between Na5 and Na7 of the same dimeric unit, a phenolate oxygen atom of a shi³⁻ ligand, and a carboxyl­ate oxygen atom of an Hshi²⁻ ligand. Na5 is not connected to any neighboring metallacryptate units. For Na6, the coordination environment consists of one μ-carbonyl oxygen atom of a bridging DMF mol­ecule that bridges between Na6 and Na4 of the same dimeric unit, one carbonyl oxygen atom of terminal DMF mol­ecule, a carboxyl­ate oxygen atom of an acetate anion that bridges between Na6 and Al11, a carboxyl­ate oxygen atom of a different acetate anion that bridges between Na6 and Na4 of the same dimeric unit, a phenolate oxygen atom of a shi³⁻ ligand, and a carboxyl­ate oxygen atom of an Hshi²⁻ ligand. Na6 is not connected to any neighboring metallacryptate units. For Na8, the coordination environment consists of three μ-carbonyl oxygen atoms of three different bridging DMF mol­ecules, a phenolate oxygen atom of a shi³⁻ ligand, a carboxyl­ate oxygen atom of a different shi³⁻ ligand, and a carboxyl­ate oxygen atom of an Hshi²⁻ ligand. The three bridging DMF mol­ecules connect Na8 to the Na9 ion of a neighboring metallacryptate. For Na9, the coordination environment consists of three μ-carbonyl oxygen atoms of three different bridging DMF mol­ecules, a carbonyl oxygen atom of a terminal DMF mol­ecule, a phenolate oxygen atom of a shi³⁻ ligand, and a carboxyl­ate oxygen atom of a different shi³⁻ ligand. The three bridging DMF mol­ecules connect Na9 to the Na8 ion of a neighboring metallacryptate. For Na10, the coordination environment consists of two μ-carbonyl oxygen atoms of two different bridging DMF mol­ecules, a carbonyl oxygen atom of a terminal DMF mol­ecule, two phenolate oxygen atoms of two different shi³⁻ ligands, and a carboxyl­ate oxygen atom of a third shi³⁻ ligand. The two bridging DMF mol­ecules connect Na10 to the Na1 ion of a neighboring metallacryptate. The series of μ-bridging DMF mol­ecules between the peripheral Na⁺ ions of the dimeric metallacryptate units of 2 generate the two-dimensional network of the compound (Fig. 5). For the dimeric unit, there are six connection points (Na1, Na2, Na3, Na8, Na9, and Na10) to neighboring metallacryptates. If the shape of the dimeric metallacryptate unit of 2 is approximated as a rectangle with Na2 and Na8 along one long edge, Na3 and Na9 along the opposite long edge, and Na1 and Na10 on opposite short edges, then each dimeric unit connects to one other dimeric unit along each edge via the μ-carbonyl oxygen atoms of the bridging DMF mol­ecules. Thus, each dimeric unit is connected to four adjacent dimeric metallacryptate units via the peripheral Na–DMF–Na connections and a two-dimensional sheet of metallacryptates is generated (Na1 to an adjacent Na10 on a short edge, Na10 to an adjacent Na1 on the opposite short edge, Na2 to an adjacent Na3 and Na8 to an adjacent Na9 along the same long edge, and Na3 to an adjacent Na2 and Na9 to an adjacent Na8 along the other long edge).

For both 1 and 2, several solvent mol­ecules are located within the two-dimensional networks. For 1 there are four DMF mol­ecules and one water mol­ecule per metallacryptate. One of the DMF mol­ecules (associated with N21) is flip disordered over two sites and refined to 0.50 (2):0.50 (2). For 2 there are 6.335 DMF mol­ecules per dimeric metallacryptate unit. The DMF mol­ecules associated with N36 and N42 are disordered over two positions and refined to 0.700 (13):0.300 (13) and to 0.661 (12):0.339 (12), respectively. In addition, three DMF mol­ecules associated with N38, N40, and N41 are partially occupied and refined to 0.806 (9), 0.682 (16), and 0.847 (14), respectively. Moreover, both 1 and 2 contain solvent-accessible voids of 988 and 832 ų, respectively. The residual electron density peaks were not arranged in an inter­pretable pattern; thus, the SQUEEZE routine as implemented in PLATON was used to account for the residual electron density (van der Sluis & Spek, 1990; Spek, 2015). The SQUEEZE procedure accounted for 313 and 235 electrons within the solvent-accessible voids of 1 and 2, respectively.

3. Supra­molecular features

For 1 and 2, numerous hydrogen bonds and weak C—H⋯O inter­actions exist within each metallacryptate, between components of the metallacryptate and the bridging DMF mol­ecules, and between the two-dimensional network and the solvent mol­ecules (Tables 7 and 8). For 1, the protonated oxime nitro­gen atoms of the two Hshi²⁻ ligands each form a hydrogen bond to the oxime oxygen atom of a neighboring shi³⁻ ligand (N7—H7⋯O22 and N9—H9⋯O13). The water mol­ecule (O42) forms hydrogen bonds to the phenolate oxygen atom of a shi³⁻ ligand (O42—H42A⋯O3) and to the carbonyl oxygen atom of a DMF mol­ecule coordinated to Na4 (O42—H42B⋯O37). In addition, O42 inter­acts with the methine group of a μ-DMF mol­ecule (C66—H66⋯O42). Two C—H⋯O inter­actions exist between the carbon–hydrogen atoms of the benzene rings of the shi³⁻ ligands with the carbonyl oxygen atoms of the μ-DMF mol­ecules that bridge between two Na⁺ ions (associated with C20 and C41). Furthermore, the DMF mol­ecules form numerous C—H⋯O inter­actions with neighboring oxygen atoms through either the methine or the methyl groups of the DMF mol­ecules. The methine groups form inter­actions with the oxime oxygen atom of a shi³⁻ ligand (associated with C69), the carboxyl­ate oxygen atom of Hshi²⁻ (associated with C78) or shi³⁻ (associated with C84) ligands, and the carbonyl oxygen atom of neighboring DMF mol­ecules (associated with C78). The methyl groups form inter­actions with the carbonyl oxygen atoms of neighboring DMF mol­ecules (associated with C67, C74, C79, C80, C83, C94, C95, and C97), the oxime oxygen atom of a shi³⁻ ligand (associated with C71), and the phenolate oxygen atom of shi³⁻ (associated with C73, C79, C98) or Hshi²⁻ (associated with C92) ligands.

Table 7 Hydrogen-bond geometry (Å, °) for 1 D—H⋯A D—H H⋯A D⋯A D—H⋯A O42—H42A⋯O3 0.84 2.08 2.868 (14) 156 O42—H42B⋯O37 0.84 2.08 2.820 (15) 146 N7—H7⋯O22 0.90 (3) 2.25 (6) 2.899 (11) 129 (5) N9—H9⋯O27 0.91 (3) 1.92 (3) 2.693 (11) 142 (6) C20—H20⋯O35i 0.95 2.65 3.483 (16) 147 C41—H41⋯O34 0.95 2.60 3.469 (14) 153 C66—H66⋯O42i 0.95 2.36 3.30 (2) 171 C67—H67A⋯O31 0.98 2.47 3.41 (2) 159 C69—H69⋯O10 0.95 2.50 3.260 (14) 137 C71—H71C⋯O16 0.98 2.56 3.363 (16) 139 C73—H73A⋯O6 0.98 2.33 3.268 (14) 159 C74—H74C⋯O38ii 0.98 2.34 3.32 (3) 177 C78—H78⋯O20iii 0.95 2.56 3.260 (14) 131 C78—H78⋯O37iii 0.95 2.65 3.524 (16) 154 C79—H79B⋯O41 0.98 2.45 3.25 (4) 139 C79—H79C⋯O18 0.98 2.48 3.446 (17) 168 C80—H80A⋯O37iii 0.98 2.52 3.470 (18) 163 C80—H80B⋯O41 0.98 2.49 3.31 (4) 140 C83—H83B⋯O40 0.98 2.35 3.309 (19) 166 C84—H84⋯O11iv 0.95 2.58 3.292 (18) 132 C84—H84⋯O23iv 0.95 2.54 3.414 (18) 153 C92—H92B⋯O21iv 0.98 2.40 3.35 (2) 164 C94—H94A⋯O41 0.98 2.47 3.32 (4) 145 C95—H95A⋯O41 0.98 2.36 3.23 (4) 147 C97—H97B⋯O31iv 0.98 2.57 3.35 (3) 137 C98—H98B⋯O24v 0.98 2.65 3.318 (19) 125 Symmetry codes: (i) ; (ii) x, y+1, z; (iii) ; (iv) ; (v) .

Table 8 Hydrogen-bond geometry (Å, °) for 2 D—H⋯A D—H H⋯A D⋯A D—H⋯A N5—H5N⋯O7 0.89 (3) 2.36 (7) 3.059 (8) 136 (7) N6—H6N⋯O10 0.87 (3) 2.46 (8) 3.004 (9) 121 (7) N11—H11N⋯O46 0.87 (3) 2.27 (6) 3.003 (8) 142 (8) N14—H14N⋯O37 0.89 (3) 2.22 (8) 2.795 (8) 122 (7) C4—H4⋯O62 0.95 2.64 3.477 (11) 147 C60—H60⋯O74i 0.95 2.55 3.287 (19) 135 C81—H81⋯O60ii 0.95 2.59 3.293 (12) 131 C123—H123⋯O68 0.95 2.48 3.333 (11) 150 C128—H12C⋯O69B 0.98 2.39 3.14 (5) 133 C130—H13B⋯O14 0.98 2.40 3.251 (10) 145 C137—H137⋯O4 0.95 2.36 3.221 (10) 151 C139—H13T⋯O19 0.98 2.53 3.459 (13) 159 C140—H140⋯O61 0.95 2.41 3.137 (11) 134 C144—H14I⋯O61 0.98 2.65 3.599 (15) 164 C153—H15G⋯O11 0.98 2.60 3.450 (13) 146 C157—H15P⋯O77iii 0.98 2.35 3.241 (19) 150 C159—H15S⋯O78iv 0.98 2.38 3.332 (14) 165 C159—H15U⋯O41 0.98 2.51 3.486 (13) 175 C162—H16F⋯O29 0.98 2.60 3.343 (15) 132 C163—H16G⋯O48iv 0.98 2.57 3.540 (14) 170 C168—H16P⋯O51 0.98 2.63 3.388 (12) 135 C169—H16T⋯O80iii 0.98 2.65 3.55 (2) 153 C171—H17C⋯O73v 0.98 2.42 3.360 (12) 161 C172—H17E⋯O66 0.98 2.61 3.518 (14) 154 C173—H173⋯O52 0.95 2.37 3.254 (9) 154 C175—H17J⋯O49 0.98 2.58 3.434 (13) 146 C183—H18H⋯O9 0.98 2.64 3.60 (3) 166 C183—H18H⋯O23 0.98 2.43 3.15 (3) 130 C184—H18K⋯O9 0.98 2.64 3.56 (2) 156 C191—H191⋯O77vi 0.95 2.64 3.48 (3) 148 C199—H19T⋯O29 0.98 2.52 3.50 (4) 179 C199—H19U⋯O36 0.98 2.59 3.39 (3) 139 C201—H20D⋯O15 0.98 2.50 3.30 (3) 139 C204—H20G⋯O68v 0.98 2.26 3.21 (5) 163 C223—H22G⋯O15 0.98 2.42 3.25 (5) 142 Symmetry codes: (i) x+1, y, z; (ii) x-1, y, z; (iii) ; (iv) ; (v) x, y+1, z; (vi) .

Complex 2 has similar hydrogen bonds and weak C—H⋯O inter­actions as 1. For 2, the protonated oxime nitro­gen atoms of the four Hshi²⁻ ligands each form a hydrogen bond to the oxime oxygen atom of a neighboring shi³⁻ ligand (N5—H5N⋯O7, N6—H6N⋯O10, N11—H11N⋯O46, and N14—H14N⋯O37). Four C—H⋯O inter­actions exist between the carbon–hydrogen atoms of the benzene rings of the shi³⁻ ligands with the carbonyl oxygen atoms of the DMF mol­ecules coordinated to the Na⁺ ions (associated with C4, C60, C81, and C123). The methyl groups of the acetate anions also form C—H⋯O inter­actions to the carbonyl oxygen atom of a DMF mol­ecule coordinated to a Na⁺ ion (C128—H12C⋯O69B) and to a phenolate oxygen atom of an Hshi²⁻ ligand (C130—H13B⋯O14). Furthermore, the DMF mol­ecules form C—H⋯O inter­actions with neighboring oxygen atoms through either the methine or the methyl groups of the DMF mol­ecules. The methine groups form inter­actions with the oxime oxygen atom of shi³⁻ ligands (associated with C137 and C173) and the carbonyl oxygen atom of neighboring DMF mol­ecules (associated with C140 and C191). The methyl groups form inter­actions with the carbonyl oxygen atoms of neighboring DMF mol­ecules (associated with C144, C157, C159, C169, C171, C172, and C204), the oxime oxygen atoms of shi³⁻ ligands (associated with C139 and C175), the phenolate oxygen atoms of shi³⁻ (associated with C168, C183, and C184) or Hshi²⁻ (associated with C201 and C223) ligands, and the carboxyl­ate oxygen atom of shi³⁻ (associated with C153, C162, C163, C183, and C199) or Hshi²⁻ (associated with C159) ligands.

4. Database survey

A survey of the Cambridge Structural Database (CSD version 5.41, update March 2020, Groom et al., 2016) reveals that there is only one other comparable metallacryptate, which is based on gallium (DIBLOS; Lutter et al., 2018). The structure contains a [3.3.1] metallacryptand topology built with six Ga^III ions instead of Al^III ions and also contains seven shi³⁻ ligands as in 1 and 2, but the gallium-based structure has one H₂shi⁻ and one Hshi²⁻ ligand as opposed to the two Hshi²⁻ ligands in 1 and 2. For the gallium-based structure, a Tb^III ion is captured in the central cavity to form the metallacryptate. The major difference between 1 and 2 and the gallium-based structure is that the latter is only a discrete mol­ecule and not a two-dimensional network. For the gallium-based structure, there are no sodium ions. Instead charge neutrality is maintained by the presence of three tri­ethyl­ammonium cations, which are not coordinated to the metallacryptates and which do not form bridges between them.

5. Synthesis and crystallization

Synthetic materials

Salicyl­hydroxamic acid (H₃shi, 99%) and dysprosium(III) nitrate penta­hydrate (99.9%) were purchased from Alfa Aesar. Hy­droxy­aluminum di­acetate (99+%) was purchased from Matheson Coleman and Bell. Sodium acetate trihydrate (certified ACS grade) was purchased from Fisher Scientific. N,N-Di­methyl­formamide (DMF, certified ACS grade) and diethyl ether (certified ACS grade) were purchased from Pharmco–Aaper. All reagents were used as received and without further purification.

General preparation of [3.3.1]DyAl₆Na₅ -metallacryptate compounds The same procedure was used to synthesize 1 and 2; however, the syntheses resulted in the crystallization of the compound in two different structures. Dysprosium(III) nitrate penta­hydrate (0.125 mmol, 55.7 mg for 1, 54.8 mg for 2), sodium acetate trihydrate (4 mmol, 544.7 mg for 1, 545.3 mg for 2), and salicyl­hydroxamic acid (2 mmol, 306.4 mg for 1, 307.2 mg for 2) were mixed in 10 mL of DMF resulting in a cloudy, slightly pink mixture. In a separate beaker, hy­droxy­aluminum di­acetate (2 mmol, 324.6 mg for 1, 325.1 mg for 2) was mixed in 10 mL of DMF, resulting in a cloudy, white mixture. The two solutions were mixed, resulting in a cloudy, slightly pink mixture and allowed to stir overnight. The solution was filtered the next day to remove a white precipitate, which was discarded, and a pale-yellow filtrate was recovered. X-ray quality crystals were grown via diethyl ether diffusion at room temperature. White, slightly pink, thin, needle-shaped crystals were recovered after 11 days for 1 and 28 days for 2.

[DyAl₆Na₅(OAc)(Hshi)₂(shi)₇(DMF)₈]·H₂O·4DMF, 1: The percentage yield was 2% (4.8 mg, 1.75x10⁻³ mmol) based on dysprosium(III) nitrate penta­hydrate.

[DyAl₆Na₅(OAc)(Hshi)₂(shi)₇(DMF)_8.5]₂·6.335DMF, 2: The percentage yield was 6% (20.4 mg, 3.77x10⁻³ mmol) based on dysprosium(III) nitrate penta­hydrate.

6. Refinement

For complex 1, the crystal under investigation was found to have two components, but the domains were not related by any meaningful twin relationship. The orientation matrices for the two components were identified using the program CELL_NOW (Sheldrick, 2008b), with the two components being related by a 3.5° rotation around the reciprocal axis 0 0 1. The structure was solved by direct methods with only the non-overlapping reflections of component 1, and the structure was refined using all reflections of component 1 (including the overlapping ones), resulting in a BASF value of 0.40356 (9). The R_int value given is for all reflections and is based on agreement between observed single and composite intensities and those calculated from refined unique intensities and domain fractions (TWINABS; Sheldrick, 2012).

For a portion of the metallacryptate mol­ecule (Dy1, Al3, Al5, O1, O5, O7, O10, O13, O14, N2, N3, N4, C8, C9, C22, C29, and C30) anisotropic displacement parameters in the bond direction were restrained to be similar using a RIGU restraint in SHELXL (esd = 0.001 Ų). In addition, to avoid correlation of the ellipsoids of Al5 and O13, their ADPs were constrained to be identical.

The geometry of the DMF mol­ecule associated with N18 was restrained to be similar to the DMF mol­ecule associated with N10 (esd = 0.02 Å), and the atoms of the DMF mol­ecule were restrained to have similar U^ij components of their ADPs (esd = 0.01 Ų; SIMU restraint in SHELXL).

A DMF mol­ecule, associated with N21, is flip disordered over two sites. The geometries of the two DMF mol­ecules were restrained to be similar to the DMF mol­ecule associated with N10 (esd = 0.02 Å). The atoms of the DMF mol­ecules were restrained to have similar U^ij components of the ADPs (esd = 0.01 Ų; SIMU restraint in SHELXL), and the U^ij components of the atoms were restrained to approximate isotropic behavior (esd = 0.01 Ų). Subject to these restraints, the occupancy ratio of the disordered DMF mol­ecule refined to 0.50 (2):0.50 (2).

For the water mol­ecule associated with O42, the oxygen–hydrogen bond distances were restrained to 0.84 (2) Å, the hydrogen–hydrogen distance was restrained to 1.36 (2) Å, and the hydrogen atoms were refined as riding on the oxygen atoms. Several hydrogen-bond distances between the hydrogen atom and the acceptor atom were restrained to expected target values (H42A to O3, H42B to O37, H7 to N7 and O21, and H9 to N9 and O27).

The amide N—H groups were refined subject to a distance constraint of 0.88 Å.

To avoid conflict between the hydrogen atoms and neighboring carbon atoms of DMF mol­ecules, the distances between the atoms (C100 with H94A, H94B, and H94C and C94 with H10G, H10H, and H10I) were restrained to at least 2.80 Å.

For the methyl-group carbon atoms C85, C86, C91, C92, C95, C101, C102, and C103, hydrogen atoms were placed in tetra­hedral positions with an ideal staggered geometry (AFIX 33 in SHELXL). All other carbon-bound hydrogen atoms were placed in calculated positions and refined as riding on their carrier atoms with C—H distances of 0.95 Å for sp² carbon atoms and 0.98 Å for methyl carbon atoms. The U_iso values for hydrogen atoms were set to a multiple of the value of the carrying carbon atom (1.2 × for sp²-hybridized carbon and nitro­gen atoms or 1.5 × for methyl carbon atoms and water oxygen atoms).

In addition, the structure of 1 contains solvent-accessible voids of 988 ų. The residual electron density peaks are not arranged in an inter­pretable pattern. The structure factors were instead augmented via reverse Fourier transform methods using the SQUEEZE routine (van der Sluis & Spek, 1990; Spek, 2015) as implemented in the program PLATON (Spek, 2020). The resultant files were used in the further refinement. (The `FAB' file with details of the SQUEEZE results is appended to the CIF file). The SQUEEZE procedure accounted for 313 electrons within the solvent-accessible voids. Additional crystal data, data collection and structure refinement details are summarized in Table 9.

Table 9 Experimental details   1 2 Crystal data Chemical formula [DyAl6Na5(C7H5NO3)2(C7H4NO3)7(C2H3O2)(C3H7NO)8]·4C3H7NO·H2O [Dy2Al12Na10(C7H5NO3)4(C7H4NO3)14(C2H3O2)2(C3H7NO)17]·6.335C3H7NO Mr 2746.57 5408.50 Crystal system, space group Monoclinic, Cc Monoclinic, Pc Temperature (K) 100 100 a, b, c (Å) 22.6809 (13), 20.5788 (11), 27.6206 (16) 28.1847 (14), 15.3683 (8), 30.7354 (16) β (°) 101.590 (2) 106.461 (2) V (Å3) 12628.9 (12) 12767.4 (11) Z 4 2 Radiation type Mo Kα Cu Kα μ (mm−1) 0.74 4.44 Crystal size (mm) 0.15 × 0.15 × 0.14 0.25 × 0.23 × 0.19   Data collection Diffractometer Bruker D8 Quest CMOS Bruker X8 Prospector CCD Absorption correction Multi-scan (SADABS; Bruker, 2014) Multi-scan (SADABS; Bruker, 2014) Tmin, Tmax 0.628, 0.746 0.488, 0.753 No. of measured, independent and observed [I > 2σ(I)] reflections 40899, 40899, 36071 154195, 38274, 36111 Rint 0.071 0.050 (sin θ/λ)max (Å−1) 0.738 0.596   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.056, 0.159, 1.05 0.053, 0.137, 1.02 No. of reflections 40899 38274 No. of parameters 1634 3599 No. of restraints 393 4954 H-atom treatment H atoms treated by a mixture of independent and constrained refinement H atoms treated by a mixture of independent and constrained refinement Δρmax, Δρmin (e Å−3) 1.38, −2.04 2.28, −1.57 Absolute structure Flack x determined using 7452 quotients [(I+)−(I−)]/[(I+)+(I−)] (Parsons et al., 2013) Refined as an inversion twin Absolute structure parameter 0.026 (5) 0.097 (3) Computer programs: APEX2 and SAINT (Bruker, 2014), SHELXS97 (Sheldrick, 2008a), SHELXL2018 (Sheldrick, 2015) shelXle (Hübschle et al., 2011), Mercury (Macrae et al., 2020), and publCIF (Westrip, 2010).

For complex 2, the structure was refined as a two-component inversion twin. The BASF value refined to 0.097 (3). In addition, several solvate DMF mol­ecules and one salicyl­hydroximate ligand of the mol­ecule show disorder or were partially occupied. Several DMF mol­ecules were also refined as disordered over two positions. Areas with extensively disordered unidentified solvate mol­ecules are present, which were accounted for using the SQUEEZE routine.

To model the disorder of the DMF mol­ecules, the following conditions were applied: For all of the solvate DMF mol­ecules except the DMF associated with N19, neighboring atoms were restrained to have similar U^ij components of their ADPs (SIMU restraints in SHELXL). All DMF mol­ecules were restrained to have similar geometries to that of the DMF mol­ecule associated with N19 (esd = 0.02 Å). The atoms of the DMF mol­ecule associated with N36, N37, N39 and N42 and the atoms C1, C6, and C99 were restrained to be approximately isotropic. The atom pairs O60 and O60B, O63 and O63B, and O70 and O70B were each given identical coord­inates and thermal parameters to avoid correlation of their positional and thermal parameters. An anti-bumping restraint was applied to avoid close contacts for partially occupied or disordered DMF mol­ecules (BUMP −0.04 in SHELXL). Subject to the above conditions, the occupancy ratio of the DMF mol­ecules associated with N20, N23, N24, N29, N30, N34, N36, and N42 refined to 0.847 (14):0.153 (14), 0.778 (14):0.222 (14), 0.661 (12):0.339 (12), 0.806 (9):0.194 (9), 0.703 (14):0.297 (14), 0.818 (14):0.182 (14), 0.700 (13):0.300 (13), and 0.661 (12):0.339 (12), respectively. Three DMF mol­ecules associated with N38, N40, and N41 were refined as partially occupied and subject to the above conditions, their occupancy fractions refined to 0.806 (9), 0.682 (16), and 0.847 (14), respectively.

To model the disorder of the salicyl­hydroximate ligand associated with N8, the neighboring atoms of the ligand were restrained to have similar U^ij components of their ADPs (SIMU restraint in SHELXL). The atom pair C50 and C50B were each given identical coordinates and thermal parameters to avoid correlation of their positional and thermal parameters. To maintain planarity of the benzene rings, the carbon atoms were restrained to lie in a common plane (esd = 0.1 ų). Subject to the above conditions, the occupancy ratio for the ligands associated with N8 refined to 0.56 (5):0.44 (5). The amide N—H groups were refined subject to a distance constraint of 0.88 Å. To avoid correlation, the atoms Al9 and N12 were each given identical thermal parameters.

For portions of the benzene rings of four different salicyl­hydroximate ligands (C31–35, C41–42, C43–C49, and C79–C84), the anisotropic displacement parameters in the bond direction were restrained to be similar using a RIGU restraint in SHELXL (esd = 0.004 Ų).

For the methyl-group carbon atoms C147, C166, C186, C187, C192, C193, C195, C196, C198, C199, C201, C202, C210, C211, C216, C217, C222, C223, C225, C226, C231, and C232, hydrogen atoms were placed in tetra­hedral positions with an ideal staggered geometry (AFIX 33 in SHELXL). All other methyl-group hydrogen atoms were allowed to rotate. All other hydrogen atoms were placed in calculated positions and refined as riding on their carrier atoms with C—H distances of 0.95 Å for sp² carbon atoms and 0.98 Å for methyl carbon atoms. The U_iso values for hydrogen atoms were set to a multiple of the value of the carrying carbon atom (1.2 × for sp²-hybridized carbon and nitro­gen atoms and 1.5 × for methyl carbon atoms).

In addition to the disordered solvate mol­ecules described above, there are additional solvent-accessible voids of 832 ų. The structure factors of 2 were augmented via reverse Fourier transform methods using the SQUEEZE routine (van der Sluis & Spek, 1990; Spek, 2015), which accounted for 235 electrons within the solvent-accessible voids. Lastly, the following low-angle reflection ( 0 0) was obscured by the beam stop and was omitted from the refinement. Further crystal data, data collection and structure refinement details are summarized in Table 9.