Synthesis and characterisation of the porous zinc phosphonate [Zn2(H2PPB)(H2O)2]·xH2O

The synthesis, structure and properties of the new microporous zinc phosphonate [Zn2(H2PPB)(H2O)2]·xH2O (denoted as CAU-25, CAU stands for Christian-Albrechts-University) are presented. The crystal structure was determined by combining single crystal and powder X-ray diffraction data. The final refinement was carried out by using the Rietveld method. The structure contains one-dimensional channels between dense, corrugated, hydrogen bonded layers with a diameter of approximately 5 A. While N2 uptake was not observed at 77 K, CO2 and H2O uptakes were measured at 298 K.

The intensely investigated field of metal-organic frameworks (MOF) offers materials with exceptional properties and remarkable structural versatility. 1The possibility of tuning certain properties by isoreticular chemistry leads to a wide field of possible applications, for example in gas storage or separation, drug delivery, proton conductivity and catalysis. 1he majority of MOFs are metal carboxylates; however, their stability towards moisture and temperature is often insufficient for applications under real life conditions.Due to the higher charge of phosphonate groups and the larger number of atoms involved in coordination to the metal ions, stronger metallinker bonding is observed, which results in more stable compounds. 2The various coordination modes and protonation states accessible to the phosphonate group also lead to large structural variability.A challenge in the synthesis of porous metal phosphonates is their tendency to form dense layered structures, and thus, the number of open framework metal phosphonates is very limited (Table S2a-d †). 2 Different strategies have been used to prevent formation of the dense layered structures.7][8][9] The corresponding triphosphonic acids that have been successfully employed are listed in Fig. 1. 1,3,5-tris-(4-Phosphonophenyl)benzene (H 6 PPB) has already been shown to lead to five metal phosphonates with a 3D framework structure (Table S3 †), [7][8][9][10]    The synthesis of the phosphonic acid H 6 PPB was carried out in a three step reaction according to the literature, 7,11 for which details can be found in the ESI.† First, 4-bromo-acetophenone was converted into tris(4-bromophenyl)benzene by cyclotrimerisation with thionylchloride. 11By nickel(II) chloride catalysed crosscoupling of this compound with triethylphosphite, 1,3,5-tris-(4-diethylphosphonophenyl)benzene was obtained. 7The hydrolysis of the diethylester to H 6 PPB was subsequently carried out in concentrated HCl. 7igh-throughput studies led to the new microporous zinc phosphonate [Zn 2 (H 2 PPB)(H 2 O) 2 ]•xH 2 O, hereafter denoted as CAU-25 (CAU stands for Christian-Albrechts-University).The system Zn 2+ : H 6 PPB : NaOH : H 2 O : CH 3 OH was studied using high-throughput methods, 12 which allow a fast and efficient investigation of different reaction parameters.Varying the molar ratios of Zn 2+ : H 6 PPB : NaOH led to the title compound CAU-25 and two other crystalline products of low long range order (see Fig. S3 and S4 †), which were not further characterized.Optimization of the molar ratios of the starting materials, the solvent mixture (H 2 O : CH 3 OH) as well as the synthesis temperature and time resulted in a highly crystalline product of CAU-25 (Table S4 †).The optimized synthesis procedure is as follows: H 6 PPB (30 mg, 55 mmol), aqueous 2 M Zn(NO 3 ) 2 (28 μL, 55 mmol), aqueous 2 M NaOH (55 μL, 110 mmol), 152 μL of deionised water and 366 μL of methanol were transferred to a Teflon-lined autoclave (V max = 2 mL) and sealed.The reactor was slowly heated to 120 °C within 24 h.The temperature was held for 24 h, and the reactor was subsequently cooled to room temperature within 16 h.The precipitate was filtered off and washed with water and methanol.
During synthesis optimisation, small single crystals (ca.50 × 10 × 10 μm 3 ) of the title compound were obtained.Singlecrystal X-ray diffraction (SC-XRD) data were recorded using a Nonius Kappa-CCD diffractometer at 173 K with monochromatic MoK α1 radiation.However, due to the small size of the single crystals and the insufficient data quality, only a structure model could be determined.Thus, a combination of force-field calculations and Rietveld refinement was used to confirm and complete this model.In the first step, the approximate model obtained from SC-XRD was optimised using the universal force field as implemented in Materials Studio. 13The thus obtained model was subsequently refined by Rietveld methods using TOPAS. 14Additional electron density was observed in the difference Fourier map which was attributed to the presence of a non-coordinating water molecule.From thermogravimetric data and sorption measurements, the presence of a second water molecule is suggested, but it could not be assigned to electron density in the difference Fourier map, possibly as a result of disorder.Due to the large unit cell, the carbon backbone of the linker molecules was refined as a rigid body.The final Rietveld plot (Fig. 2), some relevant crystal data and the final figures of merit are provided in Table 1.Further details can be found in the ESI.† In the crystal structure of CAU-25, each Zn 2+ ion exhibits a tetrahedral coordination environment consisting of four oxygen atoms of four different phosphonate groups.According to the Harris notation, 15 the phosphonate groups exhibit [2.110] and [4.211] bonding modes.Corner-sharing of the ZnO 4 polyhedra leads to the formation of dimeric Zn 2 O 7 units (Fig. 3a).These units are further connected via the phosphonate groups to form ribbons along the c-axis (Fig. 3b).Each ribbon is connected to four adjacent inorganic building units via the linker molecules (Fig. 3c) resulting in corrugated double layers of linker connected chains.
Based on O⋯O distances (Table S6 †), possible hydrogen bonding can be anticipated which connects the double layers via P-O-H⋯O-P and P-O⋯H 2 O⋯O-P hydrogen bonds (Fig. 4 and S8 †).The connection of adjacent corrugated double layers results in the formation of one-dimensional channels of approximately 5 Å in diameter along the c-axis (Fig. S9 †) as determined using the van der Waals radii of the atoms lining the pore walls.The Connolly surface (Fig. 5) generated for a probe molecule with the kinetic diameter of CO 2 (3.3 Å) indicates kinetically inaccessible intralayer cavities and accessible interlayer channels.In contrast to other porous metal phosphonates, the structure of CAU-25 is a remarkable example due to the presence of interlayer porosity.Thermogravimetric measurements (Fig. 6 and Table S7 †) showed a weight loss of 4% up to 100 °C and of 5% from 100 to 430 °C which is probably due to the loss of solvent  ).From 430 °C to 900 °C, the oxidation of the organic part occurs (obs.−41%, calc.−41%).Hence, CAU-25 was activated prior to sorption experiments at 150 °C for 18 h under reduced pressure (10 −2 kPa).CAU-25 is not porous towards N 2 at 77 K (Fig. 7, right) but towards CO 2 (0.4 mmol g −1 (1.8 wt%) at 100 kPa) (Fig. 7, left) and water (7.3 mmol g −1 (13.2 wt%), Fig. 7, right) at 298 K, which is due to the dipole-dipole interactions of the latter two adsorptives with the framework and the higher measurement temperature that allows for higher framework flexibility and faster diffusion.The water vapour isotherm shows two steps.Initially, two water molecules per formula sum are adsorbed up to p/p 0 = 0.35, which corresponds to the two hydrogen bonded water molecules in between the double layers.At higher p/p 0 values, an uptake of three additional water molecules per formula sum is observed.In theory, the interlayer channels should be accessible for larger N 2 molecules.The reasons for this size selective porosity towards CO 2 is probably due to the higher temperature at which CO 2 sorption was measured.At lower temperatures, the mobility of gas molecules in narrow channels as in CAU-25 is often limited. 7The thermal stability of CAU-25 was evaluated by comparison of the PXRD patterns of the assynthesized compound, the compound after activation and H 2 O sorption measurements and the simulated PXRD pattern (Fig.    This journal is © The Royal Society of Chemistry 2016 S10 †).While a decrease in long range order can be observed, the structure itself is retained.

Conclusions
The strategy to create porous metal phosphonates by disrupting the formation of a dense layered structure motif by adjustment of the geometry of the linker molecule seems to be very promising.Using this concept, we have been able to synthesize a new zinc phosphonate employing the triphosphonic acid 1,

Fig. 2
Fig.2The Rietveld plot for the refinement of CAU-25.The black line is the experimental data, the red line is the fit and the blue line is the difference curve.Vertical bars mark the Bragg reflection positions.

Fig. 3
Fig. 3 Structure of CAU-25, a) dimeric Zn 2 O 7 units with phosphonate groups (bonding modes [2.110] and [4.211]), b) ribbons of alternating corner-sharing Zn 2 O 7 and O 3 PC units, and c) a double layer formed through interconnection of the Zn-O-P ribbons by the linker molecules.

Fig. 4 Fig. 5
Fig. 4 Double layers of CAU-25, connected along the a-axis through hydrogen bonds (marked in red).Hydrogen bonds are postulated based on O⋯O distances.