1. Chemical context

Cucurbit[n]urils (CB[n]s) are 3D cyclic organic mol­ecules possessing a rigid hydro­phobic macrocyclic cavity, which is available for the uptake of various guest mol­ecules via non-covalent inter­actions (Lin et al., 2020). Recently, the main inter­est in cucurbit[n]uril chemistry was due to their possible applications in selective catalysis (Nandi et al., 2017), mol­ecular recognition (Barrow et al., 2015) and drug delivery (Das et al., 2019). The presence of several carbonyl oxygen atoms on both sides of the macrocyclic ring makes cucurbit[n]urils attractive ligand platforms for the design of discrete and polymeric coordination compounds, which can provide accessible channels due to the peculiarities of the arrangement of the cucurbit[n]urils in the crystal structure (Ni et al., 2013). The design of lanthanide(III) complexes with cucurbit[n]urils is particularly inter­esting because of the possible applications in mol­ecular magnetism (Ren et al., 2013) and luminescence (Matsumoto et al., 2022). Depending on the size of the macrocyclic cavity and the lanthanide(III) ionic radii, cucurbit[n]urils usually provide two to six oxygen atoms in the coord­ination sphere of the lanthanide ions (Zhang et al., 2019, 2020; Liang et al., 2013b; Zheng & Liu, 2017). In the majority of cases, the inter­action between cucurbit[n]urils and lanthan­ide(III) salts leads to the formation of discrete mononuclear assemblies with one coordinated cucurbit[n]uril (Ren et al., 2013; Ni et al., 2015); however, examples of polynuclear complexes and coordination polymers have also been reported (Zhang et al., 2019; Zhang et al., 2020; Liang et al., 2013a,b). Several lanthanide-containing complexes with cucurbit[6]urils have been reported previously (Ren et al., 2013; Zheng & Liu, 2017; Shan et al., 2016; Yang et al., 2016; Xiao et al., 2016). In the absence of additional bridging organic ligands or anionic complexes, the inter­action between Ln^III salts and cucurbit[6]uril leads to the formation of mononuclear complexes (Ren et al., 2013; Yang et al., 2016; Kovalenko et al., 2021; Samsonenko et al., 2002).

Since cucurbit[6]uril is poorly soluble in water, lanthanide complex formation is usually observed in the presence of strong mineral acids (da Silva et al., 2014) or a substantial excess of the lanthanide salt reaching 25-fold excess (Ren et al., 2013). The observed structure of lanthanide(III)–cucurbit[6]uril complexes depends upon a number of factors, which include an excess of the lanthanide salt in the reaction mixture, the counter-anion, reaction temperature and crystallization conditions.

In this work we report synthesis and crystal structure of a new mononuclear Pr^III complex with cucurbit[6]uril, [Pr(CB6)(NO₃)(H₂O)₅](NO₃)₂·9.56 H₂O (1), which was synthesized in the presence of a lowered tenfold Pr^III excess and is not isomorphous to previously reported Ln^III complexes with cucurbit[6]uril.

2. Structural commentary

The title complex 1 was prepared and isolated as colorless crystals according to a modified procedure for the analoguous Dy^III complex with cucurbit[6]uril, using Pr(NO₃)₃·6H₂O for 1 (Ren et al., 2013). The previously reported synthetic strategy employed a 25-fold excess of the Ln^III salt in order to promote the solubility of cucurbit[6]uril. In this work we introduced ultrasonication before placing the reaction mixture in hydro­thermal conditions, which allowed the excess of the Ln^III salt needed for the cucurbit[6]uril to be dissolved to be decreased.

The obtained complex [Pr(CB6)(NO₃)(H₂O)₅](NO₃)₂·9.56 H₂O (1) crystallizes in the P2₁/n space group, while previously reported complexes obtained as outcomes of inter­actions between Ln(NO₃)₃ and cucurbit[6]uril crystallized in the ortho­rhom­bic Pna2₁ space group (Ln = Gd, Dy, Ho and Yb) or in the monoclinic P2₁/n space group in the case of Ln^III (Samsonenko et al., 2002; Ren et al., 2013). The different space group in the case of 1 may be caused by a variation of the synthetic conditions or the different lanthanide(III) radii.

The unit cell of complex 1 contains eight Pr^III–cucurbituril cationic [Pr(CB6)(NO₃)(H₂O)₅]²⁺ complex mol­ecules (Fig. 1) per unit cell, non-coordinated water mol­ecules and two nitrate anions per complex cation for charge balance. There are two crystallographically independent complex cations in the asymmetric unit of 1, however, the differences in the coordination environments of the Pr^III ions are minor. The Pr^III ions in the complex 1 are nona­coordinated. Two coordination positions of the Pr^III ions are occupied by two carbonyl oxygen atoms from the coordinated CB6 ligands, two positions contain oxygen atoms from the bidentate nitrate anions and the remaining five positions are occupied by oxygen atoms from the coordinated water mol­ecules. The macrocyclic cucurbit[6]uril coordinates in bidentate mode, which is typical for Ln^III–cucurbit[n]uril complexes without additional ligands. The carbonyl oxygen atoms on the opposite side of the macrocycle remain uncoordinated.

Figure 1 The mol­ecular structure of the [Pr(CB6)(NO3)(H2O)5]2+ cation (mol­ecule A) with selected atom-labeling scheme and displacement ellipsoids drawn at the 50% level.

The Pr—O_carbon­yl bond distances in complex 1 are typical for cucurbit[6]uril complexes with Ln^III ions (Samsonenko et al., 2002; Ren et al., 2013; da Silva et al., 2014; Lin et al., 2019). The observed bond distances between the Pr^III ions and the nitrate oxygen atoms are typical for bidentately coordinated nitrate anions to Pr^III ions (Pavlishchuk et al., 2019). However, minor differences in the geometrical parameters of the coordination spheres of Pr1A and Pr1B are observed (Table 1, (Fig. 2). According to the calculations performed with Shape 2.1 software (Casanova et al., 2005, Table 2), the nona­coordinated Pr^III ions in complex 1 exhibit different geometries of the coordination environment: the Pr1A ions are located in a spherical capped square-anti­prismatic environment (CSAPR-9, C_4v), while the geometry of the Pr1B ions is best described as a muffin polyhedron (MFF-9, C_s).

Figure 2 Coordination environments of the (a) Pr1A and (b) Pr1B ions in complex 1.

3. Supra­molecular features

The cationic fragments [Pr(CB6)(NO₃)(H₂O)₅]²⁺ in complex 1 are linked to each other through an extended system of hydrogen bonds (Table 3, Figs. 3 and 4). The carbonyl oxygen atoms, which are located on opposite side of macrocycle with respect to the coordinated Pr^III ions are involved in the formation of an extended system of hydrogen-bonded water mol­ecules, which provide the supra­molecular organization of 1. The carbonyl oxygen atoms O11A, O9B and O10B from the uncoordinated sides of the CB6 ligands form hydrogen bonds with water mol­ecules in the coordination sphere of the Pr^III ions from adjacent complex cations (O11A–H4WB⋯O4WB, O11A—H5WA⋯O5WB, O9B—H5WD⋯O5WA and O10B—H4WC⋯·O4WA). In addition, there are intra­molecular hydrogen bonds that are formed between the carbonyl oxygen atoms located on the coordinated side of the CB6 ligands with the water mol­ecules coordinated to the Pr^III ions from the same [Pr(CB6)(NO₃)(H₂O)₅]²⁺ fragment (O1A—H2WC⋯O2WA, O4A—H3WC⋯O3WA, O1B—H2WB⋯O2WB and O4B—H3WB⋯O3WB). Other non-coordinated carbonyl oxygen atoms from CB6 are involved in the formation of hydrogen bonds with non-coordinated water mol­ecules located between adjacent [Pr(CB6)(NO₃)(H₂O)₅]²⁺ fragments (in complex cations with Pr1A ions: O2A—H17E⋯O17W, O3A—H17W⋯O17W, O3A—H15A⋯O15W, O7A—H4F⋯O4W, O8A—H3WF⋯O3W, O10A—H2WE⋯O2W and O12A—H11F⋯O11W; in complex cations with Pr1B ions: O2B—H12F⋯O12W, O3B—H12E⋯O12W, O7B—H19C⋯O19W, O8B—H16A⋯O16W, O11B—H14C⋯O14W and O12B—H24F⋯O24W). Water mol­ecules coordinated to Pr^III ions in 1 are also involved in the formation of hydrogen bonds with non-coordinated water mol­ecules (water mol­ecules coordinated to Pr1A: O1WA—H1WA⋯O9W, O2WA—H2WD⋯O19W, O3WA—H3WD⋯O16W, O4WA—H4WD⋯O14W, O5WA—H5WC⋯O19W; water mol­ecules coordinated to Pr1B: O2WB—H2WA⋯O11W, O3WB—H3W⋯O2W, O4WB—H4WA⋯O1W, O5WB—H5WB⋯O4W).

Table 3 Hydrogen-bond geometry (Å, °) D—H⋯A D—H H⋯A D⋯A D—H⋯A O1WB—H1WA⋯O3B 0.90 2.50 3.378 (4) 169 O2WB—H2WA⋯O11Wi 0.87 1.85 2.674 (3) 157 O2WB—H2WB⋯O1B 0.87 2.07 2.865 (3) 150 O2WB—H2WB⋯O2B 0.87 2.46 2.894 (4) 111 O3WB—H3WA⋯O2Wi 0.87 1.88 2.709 (4) 158 O3WB—H3WB⋯O4B 0.87 1.89 2.710 (3) 156 O4WB—H4WA⋯O1Wi 0.87 2.01 2.729 (4) 139 O4WB—H4WB⋯O10Aii 0.87 2.48 3.211 (3) 142 O4WB—H4WB⋯O11Aii 0.87 2.60 3.206 (3) 127 O5WB—H5WA⋯O11Aii 0.87 2.08 2.798 (4) 140 O5WB—H5WA⋯O12Aii 0.87 2.44 3.018 (3) 124 O5WB—H5WB⋯O4Wi 0.87 1.86 2.712 (4) 167 O1WA—H1WC⋯O2A 0.86 2.41 3.251 (4) 167 O1WA—H1WD⋯O7Wc 0.85 1.99 2.749 (17) 148 O1WA—H1WD⋯O8Wa 0.85 2.25 2.751 (9) 118 O2WA—H2WC⋯O1A 0.87 1.80 2.667 (3) 179 O2WA—H2WD⋯O19Wiii 0.87 1.95 2.723 (4) 147 O3WA—H3WC⋯O4A 0.87 1.87 2.723 (3) 166 O3WA—H3WD⋯O16W 0.87 1.93 2.733 (4) 153 O4WA—H4WC⋯O10Biv 0.87 2.05 2.905 (3) 167 O4WA—H4WD⋯O14Wiii 0.85 1.93 2.743 (4) 159 O5WA—H5WC⋯O19Wiii 0.87 1.93 2.766 (5) 159 O5WA—H5WD⋯O9Biv 0.87 1.97 2.676 (3) 137 O15W—H15A⋯O3A 0.87 1.97 2.837 (4) 174 O15W—H15B⋯O16B 0.87 2.19 3.019 (5) 159 O15W—H15B⋯O18B 0.87 2.39 3.128 (5) 143 O15W—H15B⋯N2B 0.87 2.53 3.394 (5) 173 O1W—H1WE⋯O21B 0.87 1.92 2.768 (4) 165 O1W—H1WF⋯O16A 0.87 1.89 2.750 (4) 170 O17Wb—H17Eb⋯O2Av 0.87 2.07 2.913 (6) 163 O17Wb—H17Fb⋯O3Av 0.87 2.46 3.045 (9) 126 O3W—H3WE⋯O4W 0.87 1.86 2.734 (4) 177 O3W—H3WF⋯O8Avi 0.87 1.98 2.764 (3) 150 O2W—H2WE⋯O9Avi 0.87 2.41 3.047 (3) 131 O2W—H2WE⋯O3W 0.87 2.06 2.850 (4) 151 O2W—H2WF⋯O10Avi 0.87 1.96 2.822 (3) 173 O21Wa—H21Aa⋯O10B 0.88 2.41 3.181 (9) 145 O21Wa—H21Ba⋯O11B 0.90 2.36 3.213 (9) 157 O21Wa—H21Ba⋯O12B 0.90 2.60 3.127 (10) 118 O19W—H19C⋯O7Bi 0.87 2.29 2.856 (4) 123 O19W—H19C⋯O8Bi 0.87 2.28 2.939 (4) 132 O19W—H19D⋯O17Wb 0.87 2.16 2.813 (7) 132 O19W—H19D⋯O18Wa 0.87 1.70 2.54 (2) 160 O14W—H14C⋯O11Bi 0.87 2.42 2.870 (4) 112 O14W—H14C⋯O12Bi 0.87 2.21 3.024 (4) 156 O14W—H14D⋯O24W 0.85 2.25 2.913 (5) 135 O6W—H6WA⋯O9A 0.86 (2) 2.29 (2) 3.101 (5) 159 (4) O6W—H6WB⋯O10A 0.87 (2) 2.31 (2) 3.117 (5) 155 (4) O16W—H16A⋯O8Biv 0.87 2.17 3.014 (4) 163 O16W—H16B⋯O15W 0.87 1.93 2.723 (4) 152 O7Wc—H7WAc⋯O6W 0.89 1.79 2.673 (17) 170 O4W—H4WE⋯O12W 0.87 1.89 2.744 (4) 166 O4W—H4WF⋯O7Avi 0.87 1.91 2.777 (3) 177 O8Wa—H8WAa⋯O6W 0.87 1.93 2.737 (9) 153 O8Wa—H8WBa⋯N21A 0.87 2.66 3.316 (9) 133 O18Wa—H18Ea⋯O2Av 0.87 2.08 2.94 (2) 171 O18Wa—H18Fa⋯O25W 0.87 2.35 2.79 (4) 111 O9Wb—H9WAb⋯N19A 0.83 2.69 3.411 (10) 146 O9Wb—H9WBb⋯O6W 0.86 1.94 2.805 (10) 177 O5W—H5WE⋯O14W 0.90 1.58 2.440 (11) 158 O5W—H5WF⋯O20Bi 0.87 1.99 2.786 (12) 151 O10W—H10A⋯O4Bi 0.87 2.21 2.981 (3) 148 O10W—H10B⋯O3W 0.87 1.83 2.697 (4) 175 O20Wb—H20Cb⋯O12B 0.87 2.00 2.86 (2) 167 O20Wb—H20Db⋯O5WAvii 0.87 2.38 3.00 (2) 128 O20Wb—H20Db⋯O19Wi 0.87 2.37 3.20 (4) 160 O11W—H11E⋯O13W 0.87 1.91 2.749 (4) 161 O11W—H11F⋯O12Avi 0.87 1.90 2.755 (4) 168 O22Wa—H22Aa⋯O21Wa 0.87 1.80 2.670 (11) 179 O22Wa—H22Ba⋯O1WB 0.87 1.93 2.763 (8) 161 O12W—H12E⋯O3Bi 0.87 2.05 2.913 (4) 169 O12W—H12F⋯O2Bi 0.87 2.15 2.918 (4) 147 O25W—H25C⋯O21A 0.87 2.02 2.872 (5) 166 O25W—H25D⋯O18Bviii 0.87 2.09 2.953 (6) 170 O13W—H13C⋯O17B 0.87 2.03 2.884 (5) 165 O13W—H13D⋯O21Aix 0.87 1.96 2.800 (4) 163 O24W—H24E⋯O25W 0.87 1.93 2.790 (5) 171 O24W—H24F⋯O12Bi 0.87 2.17 2.839 (4) 133 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) ; (v) ; (vi) ; (vii) ; (viii) ; (ix) .

Figure 3 Fragment of the crystal structure viewed along the a axis.

Figure 4 System of hydrogen bonds connecting the [Pr(CB6)(NO3)(H2O)5]2+ units in complex 1.

In summary, we have synthesized a new Pr^III complex with the macrocyclic cucurbit[6]uril ligand, which crystallizes in space group P2₁/n, while previously reported complexes with other lanthanide ions Ln^III = La, Gd, Dy, Ho and Yb crystallized in P2₁/n or Pna2₁. The crystal structure of 1 contains [Pr(CB6)(NO₃)(H₂O)₅]²⁺ complex cations, two non-coordin­ated nitrates per cation and non-coordinated water mol­ecules. Subtle differences in the bond distances and angles in the Pr^III coordination spheres leads to the observation of two crystallographically different types of Pr^III ions. The composition of the coordination sphere of two types of nona­coordinated Pr^III ions in 1 is the same, however the symmetry of the coordination environment of Pr1A and Pr1B ions is different.

4. Synthesis and crystallization

Cucurbit[6]uril was obtained by a modified procedure (Zbruyev et al., 2023). Cucurbit[6]uril (C₃₆H₃₆N₂₄O₁₂·10H₂O, CB6, 11.8 mg, 0.01 mmol) and Pr(NO₃)₃·6H₂O (42 mg, 0.1 mmol) were placed in a closed vial containing 3 mL of water and ultrasonicated for the enhancement of macrocycle solubility. The obtained suspension was heated for 1 h at 358 K in a sand bath, which was accompanied by dissolution of macrocyclic ligand. Afterwards the observed clear solution had been heated at 363 K for 2 h. Slow cooling in the sand bath led to the formation of colorless crystals of 1 in one day. IR spectra of CB6 and complex 1 are shown in Fig. 5.

Figure 5 IR spectra of CB6 and complex 1 recorded in a KBr pellet.

5. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 4. H atoms were placed in calculated positions and refined as riding.

Table 4 Experimental details Crystal data Chemical formula [Pr(NO3)(C36H36N24O12)(H2O)5](NO3)2·9.56H2O Mr 1586.05 Crystal system, space group Monoclinic, P21/n Temperature (K) 180 a, b, c (Å) 24.1937 (3), 17.01202 (19), 28.6422 (3) β (°) 90.5965 (11) V (Å3) 11788.0 (2) Z 8 Radiation type Mo Kα μ (mm−1) 0.95 Crystal size (mm) 0.25 × 0.10 × 0.05   Data collection Diffractometer Rigaku Oxford Diffraction Xcalibur, Eos Absorption correction Multi-scan (CrysAlis PRO; Rigaku OD, 2022) Tmin, Tmax 0.892, 1.000 No. of measured, independent and observed [I > 2σ(I)] reflections 75330, 20820, 17014 Rint 0.043 (sin θ/λ)max (Å−1) 0.595   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.037, 0.087, 1.04 No. of reflections 20820 No. of parameters 1843 No. of restraints 84 H-atom treatment H atoms treated by a mixture of independent and constrained refinement Δρmax, Δρmin (e Å−3) 1.26, −0.64 Computer programs: CrysAlis PRO (Rigaku OD, 2022), SHELXT (Sheldrick, 2015a), SHELXL2019/2 (Sheldrick, 2015b) and OLEX2 (Dolomanov et al., 2009).