2.1. Materials and methods

All chemicals were purchased from commercial sources and used without further purification. N,N′-Bis(3-imidazol-1-yl-propyl)-pyromellitic diimide (L, see Fig. 1) was prepared according to the previously described method (Lü et al., 2006). Elemental analyses were carried out on a Perkin–Elmer 240 elemental analyser. IR spectra were obtained on a Bruker EQUINOX55 FT–IR spectrophotometer using KBr discs in the 4000–400 cm⁻¹ region. ¹H NMR measurements were carried out on INOVA 500NB or Mercury-Plus 300 spectrometers with SiMe₄ as internal standard. The powder XRD patterns were recorded on a D/Max-IIIA diffractometer with Cu Kα radiation (λ = 1.5406 Å) at a scanning rate of 1° (2θ) min⁻¹. Thermogravimetric analysis (TGA) was performed in air at a heating rate of 10°C min⁻¹ on a NETZSCH Thermo Microbalance TG 209 F3 Tarsus. The excitation and emission spectra were obtained on a HITACHI 850 spectrometer.

Figure 1 Molecular structure of the ligand L.

2.2. Synthesis of complexes

Complexes {[AgL(CF₃CO₂)]·solvent}_n (1·solvent) in different polymorphic forms were prepared by a general method with varying crystallization times. A solution of AgCF₃CO₂ (13 mg, 0.025 mmol) in tetrahydrofuran (THF; 5 ml) was layered carefully onto a solution of L (22 mg, 0.05 mmol) in CH₂Cl₂ (10 ml) in a test tube. The solutions were left to stand for a few days at room temperature, giving gradual growth of colourless block crystals. Yield: ∼ 54%. IR (KBr, cm⁻¹): 3474w, 3111w, 2944w, 1777m, 1718vs, 1516w, 1456w, 1435w, 1397s, 1362m, 1297w, 1278w, 1238w, 1199m, 1173m, 1130s, 1043w, 1026w, 918w, 883w, 861w, 828w, 799w, 756w, 725m, 657w, 627w, 591w, 559w.

2.3. X-ray crystallography

Several crystals were randomly selected from different crystallization batches and mounted on glass fibres for structural determination, offering two apparent polymorphic forms A (Pbcm) and B (Ibam). All diffraction data were collected on a Bruker Smart 1000 CCD diffractometer with graphite-monochromated Mo Kα radiation (λ = 0.7107 Å) at room temperature using the program SMART and processed by SAINT-Plus (Bruker, 1998). Absorption corrections were applied using SADABS (Bruker, 1998) and the structures were solved by direct methods and refined using full-matrix least-squares against F² using SHELXTL (Sheldrick, 2008). Non-H atoms were refined anisotropically, while H atoms were introduced in calculated positions and refined with fixed geometry with respect to their carrier atoms. For form A, due to poor crystal quality and severe disorder of the anions and solvent molecules, the SQUEEZE procedure (van der Sluis & Spek, 1990) implemented via the WinGX suite (Farrugia, 2012) was applied to account for regions of diffuse electron density that could not be satisfactorily modeled. The coordination frameworks generally display well defined positions; however, disorder of the Ag atoms and methylene imidazole donors is evident. Refinement of the site occupancies of the disordered Ag atoms indicates an 18/82% site distribution, while the disordered methylene imidazole fraction could not be satisfactorily modelled. Some of the C and N atoms exhibiting unusual displacement parameters were refined with SIMU/ISOR restraints in SHELXTL. For form B, the Ag atoms and methylene imidazole donors display statistical disorder over two positions with 50:50% site occupancy. The CF₃CO₂⁻ anions are disordered over two C₂ symmetry-related positions, and modelled using DFIX/SADI restraints. All water solvent molecules were treated with partial occupancy and H atoms were not added. Both the anions and solvents were refined with DELU/SIMU/ISOR restraints. Crystallographic information for data collection and structural refinement is listed in Table 1, and selected bond lengths and angles are listed in Table S1 .

3.1. Synthesis and X-ray diffraction

The long ditopic, semi-flexible ligand containing a rigid three-fused-ring central base and two imidazole coordinating donors linked by two flexible propylene chains, N,N′-bis(3-imidazol-1-yl-propyl)-pyromellitic diimide (L, see Fig. 1), was prepared by reaction of pyromellitic dianhydride with 2 molar equivalents of N-3-aminopropyl-imidazole in DMF. The reaction of L with AgCF₃CO₂ in the presence of CH₂Cl₂ afforded complexes of the general formula {[AgL(CF₃CO₂)]·solvent}_n (1·solvent). The IR spectrum of the fresh sample indicated the presence of water molecules and CF₃CO₂⁻ anions in the crystals (Fig. S1 ), while ¹H NMR measurements suggested inclusion of CH₂Cl₂ solvent molecules. The relative quantities of the solvents in the crystal were estimated by thermogravimetric analysis (TGA) to be two H₂O and one CH₂Cl₂ molecule per [AgL(CF₃CO₂)]₂ unit (Fig. S2 ). The phase purity of the bulk sample was checked by comparing the measured powder X-ray diffraction (XRD) pattern with the simulations based on the single-crystal structure data (Fig. 2, see below). Solid-state photoluminescent measurements on the pure ligand and complex 1 indicated that the ligand-based emission was strengthened after coordination but keeping a similar peak profile. The emission maximum was red-shifted by 29 nm from 453 nm in the ligand to 482 nm in the complex. These findings suggest that the emission nature of the complex is basically ligand-centred (LC) but may contain a little ligand-to-metal charger-transfer (LMCT) contribution because of the presence of short Ag⋯Ag contacts (see below; Barbieri et al., 2008).

Figure 2 Comparison of powder X-ray diffraction patterns: (a) as-synthesized; (b) simulation based on the refined structure of form B; (c) simulation based on the refined structure of form A. Note that the refined structure of form A does not contain the disordered anions or solvent molecules, so the simulated diffraction pattern is only indicative.

Colourless crystals were readily available from a layered THF–CH₂Cl₂ solvent system in test tubes. Single-crystal X-ray diffraction screening of randomly selected crystals revealed that most of them, although appearing to be optically perfect, had apparently poor crystallinity. Careful structural analyses of a number of single crystals indicated the existence of two main polymorphic forms (Table 1): orthorhombic Pbcm (assigned as form A) and Ibam (assigned as form B). Most crystals probably crystallize in intermediate phases between these two forms, with varying ratios and degrees of disorder depending on the growth conditions. The difficulties are also reflected in the powder XRD patterns of the bulk sample. As seen from Fig. 2, the measured XRD pattern matches well with that simulated from the disordered form B (space group Ibam). The simulated XRD pattern based on form A (space group Pbcm) is only indicative due to omission of the solvent and anions, but all of the observed diffraction peaks also fit well with those of the measured sample. This indicates that the disorder details cannot directly be distinguished from the powder XRD data.

The chemical nature of the two crystal forms A and B can be interpreted as follows. For form B (Ibam), keeping only one or the other Ag atom site from the statistically disordered pair generates ordered crystal structures (both in space group Ibam) comprising only Ag₂L₂ rings or only polymeric (AgL)_∞ chains, respectively. Idealized CIFs corresponding to these structures (rings_Ibam.cif and chains_Ibam.cif) are included in the supporting information for reference. The statistically disordered arrangement of the Ag sites in form B indicates that the two isomers form a solid solution. For form A (Pbcm), considering only the majority (82%) positions for the Ag atoms reveals a structure in which discrete Ag₂L₂ rings and polymeric (AgL)_∞ chains alternate along the crystal a axis. An idealized CIF for this situation (both_Pbcm.cif) is also included in the supporting information . The presence of the second Ag atom site (18% site occupancy) indicates that the structure is part-way between the idealized form A structure and the form B solid solution. Thus, three idealized structures can be envisaged (all rings, all chains, alternating rings/chains along the a axis), and the actual crystals generally adopt structures partway between these.

To examine further the crystallographic origin of the problematic structural analyses, precession images in the a*c* planes of reciprocal space were reconstructed with a thickness of one pixel from the raw CCD area detector images using the CrystAlisPro program (Agilent, 2014). As shown in Fig. 3, diffuse streaks along a* are obvious in the reconstructed h0l and h1l layers for odd values of l, lying between rows of sharp Bragg reflections for even values of l. This indicates that the crystals exhibit one-dimensional disorder along the crystallographic a axis, consistent with an order/disorder type description of the structures (Moulton & Zaworotko, 2001; Bürgi et al., 2001). More detailed examination of the disorder has not been undertaken for this study; the presented interpretation of the crystallographic data is sufficient to describe the observed chemical phenomenon.

Figure 3 Simulated precession images for the h0l (a) and h1l (b) planes for a randomly selected crystal. Diffuse streaks along a* for odd values of l reveal one-dimensional disorder as described in the text.

3.2. Crystal packing and ring-opening isomerism

As shown in Figs. 4(a) and (b), a crystal with the (idealized) structure of form A consists of two clearly distinguishable structural motifs. One is the discrete Ag₂L₂ ring and the other is the polymeric (AgL)_∞ chain. The ring motif comprises two L ligands and two Ag atoms making up a large [Ag₂L₂]²⁺ rectangle with Ag—N bond distances of 2.121 (9) and 2.124 (8) Å, and an N—Ag—N angle of 171.7 (3)°. The polymeric chain comprises [AgL]⁺ repeating units that extend along the c axis with Ag—N bond distances of 2.053 (8) and 2.087 (10) Å, and with an N—Ag—N angle of 176.6 (4)°. There are strong argentophilic interactions between pairs of adjacent chains due to the short Ag⋯Ag contact [3.0776 (17) Å, significantly shorter than the sum of the van der Waals radii for two Ag atoms, 3.44 Å]. These Ag⋯Ag contacts link pairs of chains to form a twisted double-chain structure, exhibiting [(Ag_1/2)₄L₂]²⁺ rectangular subunits sharing two Ag atoms on each side. Such [(Ag_1/2)₄L₂]²⁺ metallacycles show rather similar shape to the [Ag₂L₂]²⁺ ring motifs (Fig. 4 and S4 ), and display similar interior cavity dimensions (8 × 11 Ų). The difference is the orientation of the methylene imidazole donors accompanying the shift of the Ag metal centres.

Figure 4 Structural motifs in the crystal structures of complex 1: (a) Ag2L2 ring and its space-filling model extracted from the (idealized) structure of form A; (b) twisted (AgL)∞ double chains extracted also from form A (dotted lines indicate Ag⋯Ag contacts); (c) Ag2L2 rings and (AgL)∞ double chains co-existing in a disordered fashion in form B. Differently orientated methylene imidazole donors are distinguished by the solid and dotted bonds as well as C atoms in different colours.

Although the crystal quality of form A did not permit clear identification of the disordered methylene imidazole part, free refinement of the Ag site occupancy suggests a minor occupancy (18%) disorder component. This implies that, over the whole crystal lattice, the positions mainly occupied by Ag₂L₂ rings are superimposed by 18% of (AgL)_∞ chains, and vice versa. Such structural disorder and the compatibility of the ring and chain isomers becomes even more clear in the structure of form B. As shown in Fig. 4(c), two methylene imidazole donors in each L ligand can adopt two orientations binding two different Ag atoms with statistical (50:50) occupancy. Therefore, formation of the discrete Ag₂L₂ rings and the polymeric (AgL)_∞ chains appears to have equal probability and can be envisaged to occur in any crystal growth situation. Specifically, the [Ag₂L₂]²⁺ ring has an Ag—N bond distance of 2.134 (7) Å and an N—Ag—N angle of 178.2 (4)°, while the [AgL]⁺ repeating unit in the polymeric chain has an Ag—N bond distance of 2.130 (7) Å and an N—Ag—N angle of 167.8 (4)°. The argentophilic Ag⋯Ag contact is also formed between adjacent chains [3.086 (3) Å]. The disordered site distribution of Ag metal centres and the methylene imidazole donors makes clear that either the Ag₂L₂ ring or (AgL)_∞ chains can be formed and can interconvert through rotation of the imidazole rings while retaining the same syn conformation of the pyromellitic diimide spacers. No matter which of the isomeric structural motifs is formed, the overall coordination skeleton frameworks display the same rectangular shape.

Crucially, the crystal packing in the structures of forms A and B displays generally the same architecture, as seen from Figs. 5 and S5 . If two neighbouring Ag₂L₂ rings in form A are considered to be connected via Ag⋯Ag (3.6 Å) interactions as shown in Fig. 5(a), an extended ribbon of rings is formed along the c axis. Such a ribbon is arranged parallel to the (AgL)_∞ twisted double chain. Furthermore, the one-dimensional ring ribbons and double chains alternately stack along the a axis, resulting in tubular channels made up of [Ag₂L₂]²⁺ rings (belonging to ring ribbons) and [(Ag_1/2)₄L₂]²⁺ metallacycles (belonging to double chains), which are alternately overlapped (Fig. 5b). The compatible crystal packing arrangements of the Ag₂L₂ rings and the double (AgL)_∞ chains provides the circumstances for the observed isomerism and disorder to occur in the crystalline state.

Figure 5 The compatible packing arrangements of the two kinds of structural motifs: (a) the ribbon of rings and the twisted double chains in the structure of form A: (b) the tubular channels running along the a axis formed by alternate packing of rings and chains in a parallel fashion in form A.

Insight into the disorder and crystal polymorphism offers an opportunity to realise how structural transformations between these two kinds of structural motifs could happen during the crystal growth process, which usually occurs in solution but is now manifested directly in the solid state. From the above discussion we realise that since the overall packing of the coordination skeleton frameworks can be kept static while allowing free rotation of the imidazole ring donors about the flexible propylene joints, structural conversion between Ag₂L₂ rings and (AgL)_∞ double chains can readily take place, with the N_imino donors turning from perpendicular to parallel with respect to the central pyromellitic diimide base, and vice versa. As demonstrated in Fig. 6, such rotations can enable ring-opening isomerization between the closed rings and the extended chains (e.g. Su et al., 2003; Zhang et al., 2010). In the solid state, such ring-opening isomerization has to be accompanied by a shift of the Ag centres, while in solution such structural transformation can proceed more easily, especially in the presence of extra Ag⁺ ions (see below). During the structural conversion, the central pyromellitic diimide bases retain the same syn conformation and the Ag centres keep the same linear coordination, so the ring-opening isomerization mediated by rotation of imidazole rings is subject to only minimal energy barriers. This probably accounts for the observations of the highly variable disorder of the crystallized cyclic or polymeric isomers under very similar reaction conditions.

Figure 6 Schematic representation of the ring-opening isomerization process via rotation of the methylene imidazole donors and shift of the Ag centres, resulting in interconversion between discrete rings and polymeric double chains.

The structural transformation speculated above on the basis of the solid-state observations may represent a possible scenario during real crystal growth. One unique feature of the present system is that the crystal polymorphism intrinsically relies on a ring-opening isomerization process. The observed order/disorder phenomenon reflects a highly variable ratio of cyclic and polymeric isomers within one crystal. Therefore, these crystals can be regarded as solid solutions (Yeung et al., 2013) containing varying amounts of the discrete Ag₂L₂ rings and the polymeric (AgL)_∞ chains, as well as the likely presence of finite (AgL)_n oligomers, which is distinct from normal crystal polymorphism and isomerism phenomena (Makal et al., 2011; Jiang, Li et al., 2010; Stahly, 2007; Jiang, Pan et al., 2010; Blagden & Davey, 2003). Formation of such solid solutions may be hypothesized, as illustrated in Fig. 7, to undergo concurrent crystallization and isomerization processes from the solution. In principle, a `molecular library' (Leininger et al., 2000; Lehn & Eliseev, 2001) involving discrete cyclic and oligomeric species (Yue et al., 2005; Masciocchi et al., 1998; Carlucci et al., 1998) may be expected to exist in the reaction solution. During crystallization, this mixture may converge to either discrete rings or polymeric structures, depending on the thermodynamic or kinetic contributions or the presence of specific external influences, such as intermolecular forces, concentration and template effects. Two pathways may be speculated: one is polymerization of the ring-opened species to produce coordination polymers, or reversely, cyclization of the intermediate oligomers to produce discrete rings. In both cases, ring-opening isomerization has to occur. When the ring-opening isomerization is able to take place in a bidirectional way under appropriate conditions, both cyclic and polymeric isomers may co-crystallize in the same crystal, as in the present case (Wheaton et al., 2006). Therefore, we believe that the present example may provide a unique case to shed light on the isomerization process taking place at the crystal surface, namely, structural transformation happening at the interface of the solution and solid during crystallization. Specifically, it is likely that the aromatic stacking forces may direct alignment of the solution precursors on the surface and subsequently enable the formation of either discrete rings or extended chains via ring-opening isomerization. Both cyclic and oligomeric species can act as precursors, and the interconversion between these species may be facile due to a low energy barrier for imidazole ring rotation. Usually the cyclic precursors are thermodynamically favoured in solution; however, formation of the chain structure in the present case may be aided by the argentophilic interactions between the double chains.

Figure 7 Representation of a potential crystallization process in which solid solutions containing discrete rings and coordination polymers of varying ratios are formed from equilibrium solution species via a ring-opening isomerization mechanism.

3.3. Solution studies

To obtain evidence to support the above hypothesis, solution structure investigations were carried out by means of electrospray ionization mass spectrometry (ESI-MS) and ¹H NMR. The ESI-MS spectra of 1 in DMSO or DMF display major peaks, corresponding to [AgL]⁺, [AgL₂]⁺, [Ag₂L₂(CF₃CO₂)]⁺, [Ag₃L₂(CF₃CO₂)₂]⁺ and [Ag₃L₃(CF₃CO₂)₂]⁺ species, as shown in Fig. 8. Each assignment is verified by the isotopic patterns. Further evidence for a molecular library in solution is obtained from the ¹H NMR measurements, which show only one set of proton signals in which all peaks are broadened and shifted relative to those of the `free' ligand. This clearly suggests complexation and rapid metal–ligand exchange on the NMR timescale, consistent with dynamic equilibrium between cyclic and oligomeric species in solution.

Figure 8 Partial ESI-MS spectrum of 1 (upper) and 1H NMR monitoring (lower) of the titration of AgCF3CO2 by ligand L with varying M:L ratios: (a) pure L, (b) 1:4, (c) 1:2, (d) 2:3, (e) 1:1, (f) 2:1, (g) 3:1 and (h) 4:1 (∼ 90 mM).

To explore the possible distribution of the solution species, the titration of AgCF₃CO₂ with ligand L was monitored by in situ NMR measurements. As shown in Fig. 8, when the M:L ratio is increased from 1:4 to 4:1, a general downfield increase in the proton shift (except that of H₇, see below) relative to the free ligand is observed. Detailed examination reveals that the signal shifts of these aromatic protons show three distinct steps: L:M = 2:1 and 3:2 (Figs. 8c and d), 1:1 and 1:2 (Figs. 8e and f), and 1:3 and 1:4 (Figs. 8g and h). This suggests that in the situation where the ligands are in excess, two- or three-coordinated species such as AgL₂ may predominate in solution. Conversely, when the L:M ratio is closer to or exceeds 1:1, the (AgL)_n oligomeric species may predominate in solution. A slight excess of Ag⁺ in solution may be able to facilitate the isomerization process between cyclic and oligomeric species because the structural interconversion involves not only the rotation of the imidazole rings, but also migration of the Ag⁺ ions. In the presence of additional Ag⁺, such migration may no longer be necessary. On the other hand, when a large excess of Ag⁺ is added (L:M = 1:3 and 1:4), all N donors as well as carbonyl groups (C=O) may be over-surrounded by Ag⁺ ions, which will hinder metal–ligand exchange and cause additional structural changes, thus giving rise to significantly broadened signals.

A striking finding is that while most of the protons are shifted downfield due to a loss of electron density upon coordination (Su, Cai et al., 2003), the signal of H₇, which is located on the central pyromellitic diimide base, is shifted slightly upfield. This hints at the presence of aromatic interactions in the solution similar to the aromatic stacking observed in the solid state. The staggered stacking of pyromellitic diimide in parallel will lead to edge-to-face interactions for H₇, thereby exposing this proton to a ring current shielding effect from the neighbouring molecule (Shetty et al., 1996; Adams et al., 1999; Pang et al., 1999; Zvyagin, 1988). By contrast, the protons on the propylene and imidazole fragment are only subject to electron-withdrawing effects owing to complexation.

3.4. Phase transition in the solid state

Since complex 1 displays the order/disorder phenomenon in the solid state, and structural transformation between the cyclic and polymeric isomers could take place via ring-opening isomerization, it might be expected that heating of the crystals could cause further phase transitions in the solid state. Fig. 9 illustrates variable-temperature powder XRD patterns recorded upon heating and then cooling of the bulk crystals, and Fig. 10 shows differential scanning calorimetry–thermogravimetric analysis (DSC–TGA) curves recorded in the range 25–300°C. From room temperature up to ∼ 110°C, there is a continuous initial weight loss indicative of gradual solvent escape, but the crystal phase remains intact. From ∼ 120°C, the XRD pattern starts to show new diffraction peaks, indicating the appearance of a new crystalline phase. This structural change may be triggered by a relatively abrupt solvent loss as seen from the TGA curve. The transition is irreversible, because the new diffraction pattern was retained when the sample was cooled back to 50°C. Elevating the temperature again from 50 to 250°C revealed that the first phase transition starting around 120°C was completed by ∼ 150°C, where the XRD pattern of complex 1 has been converted to a completely new one and the weight loss reached a stable region on the TGA curve. This new phase is stable up to 180°C and then a drastic structural change occurs around 200°C. The XRD pattern loses all diffraction peaks corresponding to complex 1 and the TGA curve displays a steep weight loss, indicating that the compound becomes principally amorphous, accompanied by evacuation of all remaining solvent from the crystal lattice around 200°C. During these two structural changes (the first crystal-to-crystal phase transition and the second crystal-to-amorphous phase conversion), the coordination framework of complex 1 may not fall apart because the DSC measurement verified that both transitions are endothermic, corresponding to solvent evaporation processes. Decomposition of the framework is observed later, in the temperature region from 300 to 650°C (Fig. S2 ). Attempts to collect single-crystal diffraction data for the new crystal phase around 120°C were not successful, since the crystallinity became poor upon slow heating. A possible reason may be that upon elevating the temperature and releasing the solvent, rotation of the imidazole rings and migration of Ag are promoted in the solid solutions. This would trigger structural transformation between the cyclic and polymeric isomers, although the overall packing arrangement of the ring/chain frameworks remains almost unchanged, thus leading to a crystal-to-crystal phase change. However, since the phase transition is mediated by random movements of the imidazole rings and Ag in the solid state, the disorder along the a axis is likely to become more severe upon heating, thus affording unsatisfactory Bragg reflections and diffraction patterns. In the second structural change around 200°C, the structure may become completely disordered, so as to destroy the three-dimensional crystal lattice.

Figure 9 Variable-temperature powder XRD measurements monitoring the phase transitions: the bulk sample was first heated from room temperature to 120°C, then cooled to 50°C, then heated again to 200°C.

Figure 10 DSC (blue) and TGA (black) curves for complex 1.