1. Chemical context

Exploratory synthesis has been a vital aspect of solid-state chemistry, where the discovery of new com­pounds and structure types leads to new systems that can be optimized for a desired property and even to the discovery of new unexpected properties. These unprecedented discoveries have opened doors to novel materials synthesis via the utilities of salt-inclusion chemistry (SIC) that are otherwise known as the molten-salt approach (West & Hwu, 2012). The solubility of metal oxides in molten salts facilitates the synthesis of com­plex oxide com­pounds, such as transition-metal phosphates, arsenates, and silicates (Hwu, 1998). Although occasional salt inclusion is inevitable, this approach provides added variety in structural features of the resulting solids. These solids display an integrated structure between chemically dissimilar structures of a more covalent metal oxide and a more ionic halide salt.

By a broad definition, this class of materials is called salt-inclusion solids (SISs). Alternatively, the SISs are viewed as a metal oxide covalent framework templated by an extended structural unit made of an ionic salt (Hwu et al., 2002). The characteristic feature of SISs is that the more covalent metal oxide framework consists of voids filled by ionic salt-like structural units exhibiting 0-periodicity (Tang et al., 2008), 1-periodicity (Yu et al., 2013), or 2-periodicity (Queen et al., 2008). These salt-like units usually have com­plimentary structural features with respect to the negatively charged metal oxide framework (Hwu & Mo, 2001). It is intriguing to notice that the shape of the pore windows can be varied by altering the identity and relative concentration of the incorporated salt (Huang & Hwu, 2003). Recent reports of SISs have highlighted a correlation between the incorporation of ionic salts and the formation of special frameworks that would otherwise not be isolated without the aid of molten salt as a reactive solvent in the synthesis of metal oxide frameworks with low periodicity (Morrison et al., 2016a). Many of the SISs adopt new structure types, whereby the incorporated salts play an essential role in bulk structural and chemical/physical properties. Most of the fascinating physical properties exhibited in SISs are associated with features like porous frameworks (Ulutagay et al., 1998), non-centrosymmetric structures (Etheredge & Hwu, 1995), or magnetic nanostructures (Stern et al., 2006). Inter­estingly, in some cases, SISs exhibit intense luminescence (Morrison et al., 2016b) and can have important applications as new waste forms for the safe long-term storage of radio isotopes (Morrison & zur Loye, 2016).

With increasing inter­est, the above findings convey the fact that salt inclusion is a valid tool for a broad range of synthetic chemistry, and the SISs represent a newly emerging class of solids. However, SISs have remained a challenge to synthesize as their synthesis is largely serendipitous (Gao et al., 2015). Therefore, it is important to shift the focus of this exploration toward the development of new synthesis routes that allow for the targeted growth of new com­pounds within already explored phase and com­positional space. Inspired by the study of salt-templated phosphates and arsenates of the type A₂M₃(X₂O₇)₂·(salt) (where A is K, Rb, Cs; M is Mn, Cu; X is P, As), commonly known as CU-2 materials (Huang et al., 1999), K_1.23Cs_3.60Mn₃(P₂O₇)₂Cl_3.74, K_2.12Cs_2.76Mn_0.76Cu_2.24(P₂O₇)₂Cl_2.87, K_3.81Cs_1.44Cu₃(P₂O₇)₂Cl_3.25, and Rb_1.14Cs_4.15Cu₃(As₂O₇)₂Cl_3.19, designated as CU-2-MnPO, CU-2-MnCuPO, CU-2-CuPO, and CU-2-CuAsO, respectively, we have undertaken an investigation of the salt-inclusion type CU-2-CuPO phase. The aim of this work is to design a reaction taking place by the careful selection of a metal oxide mixture aiming at the Rb₂Cu₃(P₂O₇)₂ com­position and the use of a mixed RbCl/NaCl eutectic flux to isolate salt-inclusion com­pounds of the form Rb_2–xNa_xCu₃(P₂O₇)₂·y(RbCl). Here we report a second member of CU-2-CuPO materials of which the idealized formula can be written as Rb₂Na₂Cu₆(P₂O₇)₄·7(RbCl), where the open framework is conceptually templated by extended (Rb/Na)Cl units.

2. Structural commentary

Rb₉Na₂Cu₆(P₂O₇)₄Cl₇ crystallizes with four formula units in the space group I4/mcm. To the best of our knowledge, Rb₉Na₂Cu₆(P₂O₇)₄Cl₇ represents the fourth member structurally characterized in the CU-2-MXO system (Huang et al., 1999). The crystal structure of Rb₉Na₂Cu₆(P₂O₇)₄Cl₇ can be described as having a tri-periodic framework containing channels. As shown in Fig. 1, the corner-sharing PO₄ tetra­hedra and CuO₄ square-planar units form two types of such channels ca 5.4 and 11.9 Å in diameter. This is where Rb2 (located at a site with multiplicity 16, Wyckoff letter l, symmetry m), Rb3 (16k, m) and Na1 (16l, m) cations link together with Cl2, Cl3A–D, and Cl4 anions to reside in the larger channels, while Rb1 (4c, 4/m) cations and Cl1 (4a, 422) anions occupy the smaller channels. As shown in Fig. 2(a), each smaller channel is surrounded by four larger channels and vice versa. The square-planar CuO₄ units and Cl⁻ ions form CuO₄Cl square pyramids [Fig. 2(b)]. The open framework is made of the Cu—O—P—O—Cu covalent linkages, leading to alternating CuO₄Cl units and pyrophosphate [P₂O₇] units with a shared vertex O atom O1. It shows that this bridging O1 atom occupies a special site (16l, m). There are two crystallographically distinct Cu²⁺ sites in the open framework. Cu1 and Cu2 are situated at special sites, 16j and 8h, with symmetry 2 and m2m, respectively. The Cl1 atom is common for all the Cu1O₄Cl units and is occupying the center of the smaller channel, whereas Cl2 (8h, m2m) in Cu2O₄Cl units face the center of the large channel [Fig. 2(b)].

Figure 1 Perspective view of the crystal structure of Rb9Na2Cu6(P2O7)4Cl7 along [001]. The alternating P2O7 and CuO4Cl units (given in polyhedral representation; Cu—Cl bonds have been omitted for clarity) are inter­linked through corner-sharing O atoms. The larger channel is occupied by Rb+ and Na+ cations and Cl− anions, whereas the smaller is occupied by Rb+ cations and Cl− anions.

Figure 2 (a) The channel structure of Rb9Na2Cu6(P2O7)4Cl7 in a view along [001], with the Cu–P–O framework outlined by CuO4 and P2O7 units. The channels are formed by eight (8-ring) or sixteen (16-ring) alternating cations of Cu and P. To indicate the apparent disorder of some atoms (Na, Rb, and Cl), their arrangement is highlighted in two of the large channels. (b) Projection of one large and small channel onto (001), with some Cl and all Rb and Na sites are omitted for clarity. Cl atoms occupy the apical position of the Cu2+-centered square-pyramidal CuO4Cl units (ball-and-stick drawing), with Cu—O bonds as solid lines and Cu—Cl bonds in dotted lines. The polyhedral units represent PO4 tetra­hedra.

The oxidation state of the copper cations in the CuO₄Cl square-pyramidal environment is supported through bond valence sum calculations (Brese & O'Keefe, 1991), with 2.09 valence units for Cu1 and 2.06 valence units for Cu2. Moreover, all the Cu—O bond lengths (Table 1) are consistent with what is expected from the sum of the Shannon crystal radii (Shannon, 1976) for five-coordinate Cu²⁺ and two-coordinate O²⁻ (2.00 Å), whereas the Cu—Cl bond lengths (Table 1) are somewhat longer than the sum of the Shannon crystal radii (2.46 Å) of five-coordinate Cu²⁺ (0.79 Å) and Cl⁻ (1.67).

Table 1 Selected bond lengths (Å) Cu1—O4i 1.947 (7) Cu2—O3vi 1.938 (7) Cu1—O4ii 1.947 (7) Cu2—O3vii 1.938 (7) Cu1—O2iii 1.950 (7) Cu2—Cl2viii 2.797 (9) Cu1—O2iv 1.950 (7) P1—O2 1.507 (7) Cu1—Cl1 2.7281 (19) P1—O4 1.516 (7) Cu2—O3 1.938 (7) P1—O3ix 1.520 (7) Cu2—O3v 1.938 (7) P1—O1 1.616 (4) Symmetry codes: (i) ; (ii) ; (iii) ; (iv) ; (v) ; (vi) ; (vii) ; (viii) ; (ix) .

The P atom is surrounded by four O atoms to form an almost regular tetra­hedron. The terminal P—O bond lengths average to about 1.52 Å, the sum of the Shannon crystal radii (Shannon, 1976) for P⁵⁺ (0.31 Å) and O²⁻ (1.21 Å). As expected for a condensed pyrophosphate group (Durif, 1995), the bond length to the bridging O1 atom is longer (Table 1). The calculated bond valence sum confirms the oxidation state of P⁵⁺, i.e. 4.79 valence units for P1. Fig. 3(a) shows how the salt-like parts of the structure, Rb⁺, Na⁺, and Cl⁻ ions are linked to the negatively charged wall of the Cu₃(P₂O₇)₂²⁻ framework. The three crystallographically different rubidium cations form significantly different polyhedra with oxygen and chlorine, as shown in Fig. 3(b).

Figure 3 (a) Partial structure of Rb9Na2Cu6(P2O7)4Cl7 viewed along [001], showing the building blocks of the Rb–O–Cl and NaCl fragments. A portion of the Cu–P–O framework is included to show the location of one large and one small channel. All the Rb2O6Cl3 polyhedra are included, while others are omitted for clarity. The bottom right section shows the actual arrangement of all the Rb–O–Cl polyhedral units and NaCl units. (b) The polyhedra representing the coordination around Rb1 (pink), Rb2 (green), and Rb3 (orange).

In CU-2-MXO materials (Huang et al.., 1999), the smaller channel is centered by a linear chain-like fragment of alternating A–Cl–A units (A = K, Rb, Cs), while the large channel is stuffed with mixed KCl/CsCl salt-like structure units, which adopt features characteristic for the crystal structures of NaCl and CsCl. Another series of materials adopting the framework of CU-2 topology with general formula A_xCu₆(P₂O₇)₄Cl_(x-6) (Williams et al., 2013) exhibits a wide variety of com­plex inorganic anions trapped in the large channels, with anions including chloride, bromide, phosphate and the com­plex metal halogenido anions [PtCl₄]²⁻, [PdBr₄]²⁻, [CuCl₄]²⁻, or [AuCl₄]⁻. Fig. 4(a) shows a perspective view of the Rb–Cl and Rb–Na–Cl salt structural units along [001], and Figs. 4(b)–(e) illustrate details of these units in side views. Fig. 5(a) shows the partial structure of the Rb–Na–Cl salt structural unit occupying the larger channel and running along [001]. There is disorder found at the central part of the Rb–Na–Cl salt structure creating partially occupied Na and Cl sites that form corner-sharing {Na₄Cl₈} units [Figs. 5(b)–(d) and 6)]. Four split sites for Cl3 are present within the {Na₄Cl₈} units, Cl3A (8g, 2mm), Cl3B (8g, 2mm), Cl3C (4d, mmm), and Cl3D (8g, 2mm), as well as one Cl4 (16j, 2) and one Na1(16l, m) site with an occupancy of 0.5 each. Cl3A, Cl3B, Cl3D, and Cl4 form an octa­hedron with respect to one another, shown in Fig. 6(b), where half of Cl4 would be in the axial position and the other half of the Cl4, Cl3A, and Cl3B would be in the four equatorial positions. It is intriguing to recognize the formation of structurally isolated corner-sharing {Na₄Cl₈} units that are `em­bed­ded' in the extended rubidium chloride salt structure.

Figure 4 (a) Perspective view of the Rb–Cl and Rb–Na–Cl salt-like structural units in a view along [001] (color codes: Rb1 pink, Rb2 dark green, Rb3 orange, Na1 gold, and Cl light green). (b) Ball-and-stick drawing of the extended salt structure occupying the larger channel. One Na–Cl unit (see the one in yellow) is highlighted as a polyhedral unit. (c) Extended Rb2–Cl salt structural unit forming NaCl-type fragments (top); `cubane'-like fragments formed together with Rb3 (bottom), whereby Rb2 occupies all the corners, Rb3 occupies four of the six faces, while Cl3D occupies the other two faces, and Cl4 occupies eight of the twelve edges. (d) Salt stucture extending along [001], showing the corner-sharing {Na4Cl8} units (Rb2 excluded for clarity). (e) Alternating Rb1 and Cl1 sites in the smaller channel.

Figure 5 (a) Partial structure showing the Rb–Na–Cl salt structure along [001], occupying the larger channel. (b) Extended salt structural unit in the larger channel with polyhedral representation showing the corner-sharing {Na4Cl8} units. (c) The arrangement of two corner-sharing {Na4Cl8} units centered in the faces of a `cubane'-like fragment. (d) Fragment of the Rb–Na–Cl salt structure, showing the polyhedral arrangement of Cl and Na. Displacement ellipsoids are pre­sent­ed at the 90% probability level.

Figure 6 (a) Projected view of a {Na4Cl8} unit [displacement ellipsoids as in Fig. 5(d)]. (b) The octa­hedral arrangement of Cl3A, Cl3B, Cl3D, and Cl4 in an {Na4Cl8} unit. (c) Partial structure showing the lengths between some Cl sites. (d) μ4-Cl3D-centered Na4 unit with distorted tetra­hedral shape.

Transition metals and main-group elements form especially robust clusters and their investigation provides valuable insight into how physicochemical properties evolve going from mol­ecular systems to the solid state (Berry, 1993). Much attention has been paid to studies on sodium chloride clusters using theoretical approaches, especially on the structural shapes and relative stabilities in neutral and charged clusters (Zhang & Chen, 2003). We hope that the structurally isolated {Na₄Cl₈} units in the title com­pound can be relevant for the discussion of the nature of chemical bonding for the theoreticians to apply a simple electrostatic model to describe the energies and stabilities of this sodium chloride unit based on inversion pair potentials. Furthermore, controlling the inter­action between the two chemically dissimilar structural units (halides and oxides) may give rise to new material design by placing efforts on the targeted growth of salt-inclusion com­pounds via the careful selection of systems and the use of a mixed alkali halide eutectic flux.

3. Synthesis and crystallization

Single crystals of Rb₉Na₂Cu₆(P₂O₇)₄Cl₇ were grown using a eutectic RbCl/NaCl flux in a fused-silica ampoule. The eutectic flux used was 53% RbCl (Alfa, 99.8%) and 47% NaCl (Strem, 99.999%) by moles (melting point 823.4 K). The reactants were ground and loaded in a nitro­gen-blanketed dry box and then sealed under vacuum prior to heating. Crystals were grown by introducing the reactants, i.e. P₄O₁₀ (2.1 mmol, Aldrich, 98+%), Rb₂O (2.1 mmol, Aldrich, 99+%), and CuO (6.3 mmol, Alfa, 99.7%), to the eutectic RbCl/NaCl flux with a flux-to-charge ratio of 3:1. The resulting mixture was loaded into a silica ampoule and the reaction mixture was heated to 923 K at a rate of 2 K min⁻¹, dwelled for 2 d and then cooled slowly to 573 K at a rate of 0.1 K min⁻¹, followed by cooling to room tem­per­a­ture at a rate of 3 K min⁻¹. Irregular-shaped light-green crystals of Rb₉Na₂Cu₆(P₂O₇)₄Cl₇ (Fig. 7) were isolated manually and washed with deionized water using suction filtration methods.

Figure 7 Crystal aggregates of Rb9Na2Cu6(P2O7)4Cl7 obtained from a RbCl/NaCl eutectic flux.

4. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 2. The final Fourier difference synthesis showed the maximum residual electron density of 2.37 e Å⁻³ located at 1.82 Å from Na1 and the minimum of −4.12 e Å⁻³ directly at the Cl3C position. Refinements were carried out in com­parison with the parent structure of Rb₉Cu₆(P₂O₇)₄(CuCl₇) (Williams et al., 2013). All positions remained the same up to the point of Cu being exchanged for Na, which, in turn, alters the sites of some Cl atoms as well. The parent structure has the Cu3 atom position at Wyckoff site 4b and is fully occupied. When Cu is exchanged by Na on this site, the Na position changes to Wyckoff site 16l and becomes half-occupied to maintain charge neutrality. This can be attributed to the larger size of sodium needing to shift slightly off the special position into a general position, which disturbs the channel that contains the chloride anions. In the parent structure, Cl1 is positioned at Wyckoff site 16j and corresponds to the disordered Cl3 and Cl4 sites reported herein. Cl3 was split into four sites, Cl3A, Cl3B, Cl3C, and Cl3D, with site occupation factors of 0.167, 0.333, 0.667, and 0.167, adding up to half-occupancy for Cl3, which is half of what is reported in the parent structure. To maintain charge neutrality, Cl4 was added at Wyckoff site 16j with half-occupancy to obtain charge neutrality. It is important to note that in com­parison to the parent structure, Cl2 and Cl3 correspond to Cl1 and Cl2 within the structure pre­sent­ed herein. The observed minimum electron density noted above indicates that another spliting of the Cl3C site might be necessary, but the refinement in this case resulted in models that were not meaningful.

Table 2 Experimental details Crystal data Chemical formula Rb9Na2Cu6(P2O7)4Cl7 Mr 2140.36 Crystal system, space group Tetragonal, I4/mcm Temperature (K) 298 a, c (Å) 17.840 (3), 13.483 (3) V (Å3) 4291.2 (15) Z 4 Radiation type Mo Kα μ (mm−1) 13.90 Crystal size (mm) 0.09 × 0.07 × 0.05   Data collection Diffractometer Bruker D8 Quest Photon 3 CCD Absorption correction Multi-scan (SADABS; Krause et al., 2015) Tmin, Tmax 0.849, 1.000 No. of measured, independent and observed [I > 2σ(I)] reflections 18814, 1105, 1048 Rint 0.058 (sin θ/λ)max (Å−1) 0.606   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.063, 0.164, 1.12 No. of reflections 1105 No. of parameters 98 No. of restraints 30 Δρmax, Δρmin (e Å−3) 2.37, −4.12 Computer programs: APEX3 and SAINT (Bruker, 2017), SHELXT (Sheldrick, 2015a), SHELXL (Sheldrick, 2015b), CrystalMaker (Palmer, 2014) and publCIF (Westrip, 2010).