research communications
of clofarabine (form I), C10H11ClFN5O3, from synchrotron power diffraction data and density functional theory calculations
aNorth Central College, Department of Chemistry, 131 S. Loomis St., Naperville IL 60540, USA, bNorth Central College, Department of Physics, 131 S. Loomis St., Naperville IL 60540, USA, cDepartment of Chemistry, Illinois Institute of Technology, 3101 S. Dearborn St., Chicago IL 60616, USA, dICDD, 12 Campus Blvd., Newtown Square, PA 19073-3273, USA, and eICDD, 12 Campus Blvd., Newtown Square, PA 19073-327,3 , USA
*Correspondence e-mail: [email protected]
The of clofarabine (form I) [systematic name: 2-chloro-9-(2-deoxy-2-fluoro-β-D-arabinofuranosyl)-9H-purin-6-amine], C10H11ClFN5O3, has been solved and refined using synchrotron X-ray powder diffraction data, and optimized using density functional theory techniques. The oxolane ring adopts an envelope conformation and the angle between the mean ring planes is 88.4 (2)°, resulting in an L-shaped molecule. The molecules stack along the short a-axis direction, and N—H⋯O, O—H⋯N and N—H⋯N hydrogen bonds link them into a three-dimensional network.
1. Chemical context
Clofarabine, C10H11ClFN5O3 (marketed as Clolar, Evoltra and Clofarex in different countries) is a purine nucleoside antimetabolite, used to treat relapsed or refractory acute lymphoblastic leukemia in children and young adults (Bonate et al., 2006
). Clofarabine is administered intravenously and functions by inhibiting DNA synthesis and ribonucleoside reductase. The systematic name (CAS Registry Number 123318-82-1) is (2R,3R,4S,5R)-5-(6-amino-2-chloropurin-9-yl)-4-fluoro-2-(hydroxymethyl)oxolan-3-ol.
A powder pattern for clofarabine (form I) has been reported in Chinese Patent CN101407640A (Xia et al., 2011
). Un-named crystalline forms of clofarabine are claimed in US Patent 5,034,518 (Montgomery & Secrist, 1991
; Southern Research Institute) and US Patent 5,661,136 (Montgomery & Secrist, 1997
; Southern Research Institute). Xia et al. suggest that these earlier forms were monohydrates, and claim that their form is new. The present work was carried out as part of a project (Kaduk et al., 2014
) to determine the crystal structures of large-volume commercial pharmaceuticals, and includes high-quality powder diffraction data for them in the Powder Diffraction File (Kabekkodu et al., 2024
).
2. Structural commentary
The synchrotron X-ray powder pattern of clofarabine is similar enough to that reported by Xia et al. (2011
) for form I (Fig. 1
) to conclude that they represent the same material. The patent pattern exhibits significant displacement/transparency peak position errors, as well as substantial preferred orientation.
| Figure 1 Comparison of the synchrotron pattern of clofarabine Form I (black) to that reported by Xia et al. (2011 |
The mean plane of the C16–C20/N6–N9 purine ring system of the asymmetric molecule lies approximately in the (12) Miller plane, and the mean plane of the C11–C14/O3 oxolane ring is aligned approximately with (
22). The latter ring adopts an envelope conformation with atom C12 as the flap. The angle between the mean ring planes is 88.4 (2)°, so the molecules may be described as L-shaped (Fig. 2
). The root-mean-square difference of the non-H atoms in the Rietveld-refined and VASP-optimized structures of clofarabine, calculated using the Mercury (Macrae et al., 2020
) CSD-Materials/search/crystal packing similarity tool is 0.078 Å (Fig. 3
); the structures are essentially identical. The root-mean-square Cartesian displacement of the non-H atoms in the refined and optimized structures, calculated using the Mercury Calculate molecule overlay tool, is 0.048 Å (Fig. 4
). The agreements are within the normal range for correct structures (van de Streek & Neumann, 2014
). The remaining discussion will emphasize the VASP-optimized structure.
| Figure 2 The molecular structure of clofarabine, showing 50% probability spheroids/ellipsoids. |
| Figure 3 Comparison of the Rietveld-refined (colored by atom type) and VASP-optimized (pale green) structures of clofarabine, calculated using the Mercury CSD-Materials/Search/Crystal Packing Similarity tool. The root-mean-square Cartesian displacement is 0.078 Å. |
| | Figure 4 Comparison of the refined structure of clofarabine (red) to the VASP-optimized structure (blue). The comparison was generated using the Mercury Calculate/Molecule Overlay tool; the r.m.s. difference is 0.048 Å. |
All of the bond distances, bond angles, and torsion angles fall within the normal ranges indicated by a Mercury Mogul geometry check (Macrae et al., 2020
). Quantum chemical geometry optimization of the isolated clofarabine molecule (DFT/B3LYP/6-31G*/water) using Spartan '24 (Wavefunction, 2025
) indicated that the observed conformation is 5.2 kcal mol−1 higher in energy than a local minimum, which has a very similar conformation. The global minimum-energy conformation is 14.8 kcal mol−1 lower in energy, but is folded on itself to form intramolecular O—H⋯N hydrogen bonds. Intermolecular interactions are thus important in determining the observed solid-state conformation.
3. Supramolecular features
Viewed down the short a-axis direction (Fig. 5
) the structure exhibits discrete clofarabine molecules. When viewed down the c-axis direction (Fig. 6
) a herringbone arrangement of molecules is apparent. The shortest ring centroid–ring centroid distance is 5.067 (2) Å, as the molecules stack along the a-axis direction.
| | Figure 5 Crystal structure of clofarabine, viewed down the a axis. |
| Figure 6 Crystal structure of clofarabine, viewed down the c axis. |
Analysis of the contributions to the total crystal energy of the structure using the Forcite module of Materials Studio (Dassault Systèmes, 2025
) indicated that the intramolecular energy is dominated by angle distortion terms, as might be expected for a molecule containing a fused ring system. The intermolecular energy is dominated by van der Waals attractions, which in this force-field based analysis include hydrogen bonds. The hydrogen bonds are better discussed using the results of the DFT calculation.
There are several hydrogen bonds in the structure (Table 1
). The amino group N10 acts as a donor in two classical hydrogen bonds, one to the hydroxyl group O4 and to another amino group N10. The energy of the N10—H30⋯O4 hydrogen bond is 5.6 kcal mol−1, calculated using the correlation of Wheatley & Kaduk (2019
). The hydroxyl groups O4 and O5 form strong O—H⋯N hydrogen bonds to the ring N atoms N7 and N8, respectively. These link the molecules into chains along the b-axis direction, with graph set descriptors (Etter, 1990
; Bernstein et al., 1995
; Motherwell et al., 2000
) C11(8), C11(9) and C22(11). The N—H⋯O and N—H⋯N hydrogen bonds link the molecules along the c-axis direction, with graph sets C11(10) and C11(2). These and other larger patterns result in a three-dimensional hydrogen bond network. Four intra- and inter-molecular C—H⋯O hydrogen bonds also contribute to the lattice energy.
|
The volume enclosed by the Hirshfeld surface of clofarabine (Fig. 7
; Hirshfeld, 1977
; Spackman et al., 2021
) is 299.22 Å3 or 97.94% of 1/4 of the unit-cell volume. The packing density is thus typical. The only significant close contacts (red in Fig. 9) involve the hydrogen bonds. The volume/non-hydrogen atom is smaller than normal, at 15.3 Å3.
| Figure 7 The Hirshfeld surface of clofarabine. Intermolecular contacts longer than the sums of the van der Waals radii are colored blue, and contacts shorter than the sums of the radii are colored red. Contacts equal to the sums of radii are white. |
The Bravais–Friedel–Donnay–Harker (Bravais, 1866
; Friedel, 1907
; Donnay & Harker, 1937
) algorithm suggests that we might expect elongated morphology for crystallites of clofarabine, with [100] as the long axis. A second-order spherical harmonic model for preferred orientation was included. The texture index was 1.017, indicating that the preferred orientation was slight in this rotated capillary specimen.
4. Database survey
A search in the Cambridge Structural Database (CSD, 2026.1.0; Groom et al., 2016
), combined with the chemistry C, H, Cl, F, N, and O only, yielded no hits.
5. Synthesis and crystallization
Clofarabine is a commercial reagent, purchased from TargetMol (Batch #132343), and was used as-received.
6. Refinement
Crystal data, data collection and structure details are summarized in Table 2
. The white powder was packed into a 1.5 mm diameter Kapton capillary, and rotated during the measurement at ∼50 Hz. The powder pattern was measured at 295 K at beam line 11-BM (Lee et al., 2008
; Wang et al., 2008
; Antao et al., 2008
) of the Advanced Photon Source at Argonne National Laboratory using a wavelength of 0.4687342 Å from 0.5–50° 2θ with a step size of 0.001° and a counting time of 0.1 sec step−1. The high-resolution powder diffraction data were collected using twelve silicon crystal analyzers that allow for high angular resolution, high precision, and accurate peak positions. A mixture of silicon (NIST SRM 640c) and alumina (NIST SRM 676a) standards (ratio Al2O3:Si = 2:1 by weight) was used to calibrate the instrument and refine the monochromatic wavelength used in the experiment.
|
The pattern was indexed on a primitive orthorhombic with a = 5.06685, b = 10.79310, c = 22.33892 Å, V = 1225.6 Å3, and Z = 4 using N-TREOR as incorporated into EXPO2014 (Altomare et al., 2013
). The suggested space group was P212121, which was confirmed by the successful solution and refinement of the structure.
The molecular structure of clofarabine was downloaded from PubChem (Kim et al., 2023
) as Conformer3D_COMPOUND_CID_119182.sdf. It was converted to a *.mol2 file using Mercury (Macrae et al., 2020
), and to a Fenske–Hall Z-matrix using OpenBabel (O'Boyle et al., 2011
). The structure was solved using parallel tempering techniques as implemented in FOX (Favre-Nicolin & Černý, 2002
).
Rietveld refinement was carried out using GSAS-II (Toby & Von Dreele, 2013
). Only the 2.0–35.0° portion of the pattern was included in the refinements (dmin = 0.779 Å). All non-H bond distances and angles were subjected to restraints, based on a Mercury Mogul geometry check (Sykes et al., 2011
; Bruno et al., 2004
). The Mogul average and standard deviation for each quantity were used as the restraint parameters. The aromatic fused ring system was restrained to be planar. The restraints contributed 1.4% to the overall χ2. The hydrogen atoms were included in calculated positions, which were recalculated during the refinement using Materials Studio (Dassault Systèmes, 2025
). The Cl atom was refined anisotropically. The other Uiso(H) values were grouped by chemical similarity. The peak profiles were described using the generalized microstrain model (Stephens, 1999
). The background was modeled using a six-term shifted Chebyshev polynomial, with a peak at 5.89° to model the scattering from the Kapton capillary and any amorphous component of the sample.
The final refinement of 92 variables using 33,001 observations and 56 restraints yielded the residuals Rwp = 0.0856 and GOF = 2.11. The largest peak (0.65 Å from Cl1) and hole (0.36 Å from Cl1) in the difference-Fourier map are 0.459 (12) and −0.594 (12) e Å−3, respectively. The final Rietveld plot is shown in Fig. 8
. The largest features in the normalized error plot are in the positions and shapes of some of the strong low-angle peaks, and may indicate a change in the specimen during the measurement.
| | Figure 8 The Rietveld plot for clofarabine. The blue crosses represent the observed data points, and the green line is the calculated pattern. The cyan curve is the normalized error plot, and the red line is the background curve. The blue tick marks indicate the peak positions. The vertical scale has been multiplied by a factor of 20× for 2θ > 15.5°. |
The of clofarabine was optimized (fixed experimental unit cell) with density functional theory techniques using VASP (Kresse & Furthmüller, 1996
) through the MedeA graphical interface (Materials Design, 2024
). The calculation was carried out on 32 cores of a 144-core (768 Gb memory) HPE Superdome Flex 280 Linux server at North Central College. The calculation used the GGA-PBE functional, a plane wave cutoff energy of 400.0 eV, and a k-point spacing of 0.5 Å−1 leading to a 3 × 2 × 1 mesh, and took ∼8.1 h. Single-point density functional theory calculations (fixed experimental cell) and population analysis were carried out using CRYSTAL23 (Erba et al., 2023
). Fixed experimental cell) and population analysis were carried out using CRYSTAL17 (Dovesi et al., 2018
). The basis sets for the H, C, N and O atoms in the calculation were those of Gatti et al. (1994
), and those for F and Cl were those of Peintinger et al. (2013
). The calculations were run on a 3.5 GHz PC using 8 k-points and the B3LYP functional, and took ∼1.4 h.
Supporting information
contains datablocks clofarabine, clofarabine_VASP. DOI: https://doi.org/10.1107/S2056989026006584/hb8221sup1.cif
| C10H11ClFN5O3 | Z = 4 |
| Mr = 303.68 | Dx = 1.651 Mg m−3 |
| Orthorhombic, P212121 | Synchrotron radiation, λ = 0.46873 Å |
| a = 5.067481 (12) Å | µ = 0.04 mm−1 |
| b = 10.79402 (2) Å | T = 295 K |
| c = 22.34124 (5) Å | cylinder, 2.0 × 1.5 mm |
| V = 1222.03 (1) Å3 |
| 11-BM, APS diffractometer | Scan method: step |
| Specimen mounting: Kapton capillary | 2θmin = 0.510°, 2θmax = 49.995°, 2θstep = 0.001° |
| Data collection mode: transmission |
| Least-squares matrix: full | 92 parameters |
| Rp = 0.072 | 56 restraints |
| Rwp = 0.085 | 16 constraints |
| Rexp = 0.041 | Weighting scheme based on measured s.u.'s |
| R(F2) = 0.06753 | (Δ/σ)max = 13.147 |
| 49486 data points | Background function: Background function: "chebyschev-1" function with 6 terms: 42.46(6), -8.82(9), -9.57(8), 2.83(8), -1.00(7), 2.56(7), Background peak parameters: pos, int, sig, gam: 5.889(10), 4.22(8)e3, 4.12(15)e3, 0.100, |
| Profile function: Finger-Cox-Jephcoat function parameters U, V, W, X, Y, SH/L: peak variance(Gauss) = Utan(Th)2+Vtan(Th)+W: peak HW(Lorentz) = X/cos(Th)+Ytan(Th); SH/L = S/L+H/L U, V, W in (centideg)2, X & Y in centideg 1.163, -0.126, 0.063, 0.000, 0.000, 0.002, | Preferred orientation correction: Simple spherical harmonic correction Order = 2 Coefficients: 0:0:C(2,0) = -0.2134(29); 0:0:C(2,2) = 0.199(4) |
| x | y | z | Uiso*/Ueq | ||
| Cl1 | 0.0189 (2) | 0.16598 (9) | 0.02919 (5) | 0.0491 | |
| F2 | 0.8827 (3) | 0.21882 (16) | 0.24051 (9) | 0.0404 (4)* | |
| O3 | 0.3887 (4) | 0.0218 (2) | 0.29218 (10) | 0.0404 (4)* | |
| O4 | 0.8336 (4) | 0.1997 (2) | 0.38062 (10) | 0.0404 (4)* | |
| O5 | 0.7624 (5) | −0.1464 (2) | 0.33800 (11) | 0.0543 (8)* | |
| N6 | 0.5950 (5) | 0.0280 (2) | 0.19828 (9) | 0.0276 (3)* | |
| N7 | 0.8275 (5) | −0.1145 (2) | 0.14655 (11) | 0.0276 (3)* | |
| N8 | 0.3110 (5) | 0.1027 (2) | 0.11892 (10) | 0.0276 (3)* | |
| N9 | 0.3786 (5) | −0.0050 (2) | 0.02505 (9) | 0.0276 (3)* | |
| N10 | 0.7125 (5) | −0.1486 (2) | 0.01227 (11) | 0.0276 (3)* | |
| C11 | 0.4845 (5) | 0.1019 (2) | 0.24741 (11) | 0.0404 (4)* | |
| C12 | 0.7673 (5) | 0.1167 (3) | 0.33294 (12) | 0.0404 (4)* | |
| C13 | 0.6750 (5) | 0.1895 (2) | 0.27873 (12) | 0.0404 (4)* | |
| C14 | 0.5214 (6) | 0.0417 (3) | 0.34917 (13) | 0.0404 (4)* | |
| C15 | 0.5802 (7) | −0.0816 (3) | 0.37589 (16) | 0.0543 (8)* | |
| C16 | 0.5031 (5) | 0.0297 (3) | 0.14087 (9) | 0.0276 (3)* | |
| C17 | 0.7914 (6) | −0.0585 (3) | 0.19924 (11) | 0.0276 (3)* | |
| C18 | 0.6444 (6) | −0.0584 (3) | 0.11009 (10) | 0.0276 (3)* | |
| C19 | 0.5783 (6) | −0.0731 (3) | 0.04870 (10) | 0.0276 (3)* | |
| C20 | 0.2718 (6) | 0.0791 (3) | 0.06104 (11) | 0.0276 (3)* | |
| H21 | 0.30900 | 0.14393 | 0.23107 | 0.0526* | |
| H22 | 0.93174 | 0.06037 | 0.32382 | 0.0526* | |
| H23 | 0.57838 | 0.27853 | 0.28915 | 0.0526* | |
| H24 | 0.38326 | 0.09796 | 0.37362 | 0.0526* | |
| H25 | 0.40893 | −0.13251 | 0.38656 | 0.0706* | |
| H26 | 0.68813 | −0.06089 | 0.41746 | 0.0706* | |
| H27 | 0.89907 | −0.08325 | 0.23913 | 0.0358* | |
| H28 | 0.97473 | 0.25980 | 0.36946 | 0.0526* | |
| H29 | 0.75868 | −0.23048 | 0.35566 | 0.0706* | |
| H30 | 0.66866 | −0.15293 | −0.03273 | 0.0358* | |
| H31 | 0.82978 | −0.21654 | 0.02850 | 0.0358* |
| U11 | U22 | U33 | U12 | U13 | U23 | |
| Cl1 | 0.0463 (9) | 0.0535 (9) | 0.0474 (10) | 0.0085 (15) | −0.0268 (15) | 0.0218 (16) |
| Cl1—C20 | 1.740 (2) | C14—C12 | 1.529 (3) |
| F2—C13 | 1.392 (2) | C14—C15 | 1.489 (3) |
| O3—C11 | 1.408 (3) | C14—H24 | 1.076 (3) |
| O3—C14 | 1.456 (3) | C15—O5 | 1.435 (4) |
| O4—C12 | 1.432 (3) | C15—C14 | 1.489 (3) |
| O4—H28 | 0.997 (2) | C15—H25 | 1.055 (4) |
| O5—C15 | 1.435 (4) | C15—H26 | 1.101 (4) |
| O5—H29 | 0.990 (2) | C16—N6 | 1.365 (2) |
| N6—C11 | 1.468 (3) | C16—N8 | 1.345 (2) |
| N6—C16 | 1.365 (2) | C16—C18 | 1.375 (2) |
| N6—C17 | 1.364 (2) | C17—N6 | 1.364 (2) |
| N7—C17 | 1.336 (3) | C17—N7 | 1.336 (3) |
| N7—C18 | 1.375 (2) | C17—H27 | 1.079 (2) |
| N8—C16 | 1.345 (2) | C18—N7 | 1.375 (2) |
| N8—C20 | 1.333 (2) | C18—C16 | 1.375 (2) |
| N9—C19 | 1.357 (2) | C18—C19 | 1.421 (3) |
| N9—C20 | 1.328 (2) | C19—N9 | 1.357 (2) |
| N10—C19 | 1.338 (3) | C19—N10 | 1.338 (3) |
| N10—H30 | 1.031 (2) | C19—C18 | 1.421 (3) |
| N10—H31 | 1.011 (2) | C20—Cl1 | 1.740 (2) |
| C11—O3 | 1.408 (3) | C20—N8 | 1.333 (2) |
| C11—N6 | 1.468 (3) | C20—N9 | 1.328 (2) |
| C11—C13 | 1.522 (2) | H21—C11 | 1.064 (3) |
| C11—H21 | 1.064 (3) | H22—C12 | 1.052 (3) |
| C12—O4 | 1.432 (3) | H23—C13 | 1.103 (3) |
| C12—C13 | 1.518 (2) | H24—C14 | 1.076 (3) |
| C12—C14 | 1.529 (3) | H25—C15 | 1.055 (4) |
| C12—H22 | 1.052 (3) | H26—C15 | 1.101 (4) |
| C13—F2 | 1.392 (2) | H27—C17 | 1.079 (2) |
| C13—C11 | 1.522 (2) | H28—O4 | 0.997 (2) |
| C13—C12 | 1.518 (2) | H29—O5 | 0.990 (2) |
| C13—H23 | 1.103 (3) | H30—N10 | 1.031 (2) |
| C14—O3 | 1.456 (3) | H31—N10 | 1.011 (2) |
| C11—O3—C14 | 111.81 (18) | C12—C13—H23 | 114.8 (2) |
| C12—O4—H28 | 112.9 (2) | O3—C14—C12 | 104.3 (2) |
| C15—O5—H29 | 101.5 (3) | O3—C14—C15 | 108.1 (3) |
| C11—N6—C16 | 124.40 (19) | C12—C14—C15 | 113.9 (3) |
| C11—N6—C17 | 129.7 (2) | O3—C14—H24 | 103.1 (2) |
| C16—N6—C17 | 105.86 (14) | C12—C14—H24 | 110.6 (3) |
| C17—N7—C18 | 103.30 (17) | C15—C14—H24 | 115.5 (3) |
| C16—N8—C20 | 110.43 (17) | O5—C15—C14 | 109.2 (3) |
| C19—N9—C20 | 115.96 (16) | O5—C15—H25 | 114.1 (3) |
| C19—N10—H30 | 120.8 (2) | C14—C15—H25 | 113.1 (3) |
| C19—N10—H31 | 121.5 (2) | O5—C15—H26 | 106.1 (3) |
| H30—N10—H31 | 116.3 (2) | C14—C15—H26 | 104.9 (3) |
| O3—C11—N6 | 109.2 (2) | H25—C15—H26 | 108.9 (3) |
| O3—C11—C13 | 105.89 (15) | N6—C16—N8 | 126.72 (15) |
| N6—C11—C13 | 116.1 (2) | N6—C16—C18 | 106.42 (13) |
| O3—C11—H21 | 102.6 (3) | N8—C16—C18 | 126.86 (15) |
| N6—C11—H21 | 107.12 (19) | N6—C17—N7 | 113.30 (17) |
| C13—C11—H21 | 115.0 (2) | N6—C17—H27 | 123.5 (2) |
| O4—C12—C13 | 110.0 (2) | N7—C17—H27 | 123.1 (3) |
| O4—C12—C14 | 110.2 (3) | N7—C18—C16 | 111.09 (15) |
| C13—C12—C14 | 102.26 (17) | N7—C18—C19 | 132.98 (18) |
| O4—C12—H22 | 108.7 (2) | C16—C18—C19 | 115.92 (15) |
| C13—C12—H22 | 112.9 (3) | N9—C19—N10 | 118.15 (19) |
| C14—C12—H22 | 112.7 (3) | N9—C19—C18 | 119.43 (17) |
| F2—C13—C11 | 109.8 (2) | N10—C19—C18 | 122.37 (19) |
| F2—C13—C12 | 112.0 (2) | Cl1—C20—N8 | 113.75 (17) |
| C11—C13—C12 | 103.89 (15) | Cl1—C20—N9 | 114.91 (16) |
| F2—C13—H23 | 105.51 (19) | N8—C20—N9 | 131.13 (19) |
| C11—C13—H23 | 110.9 (2) |
| C10H11ClFN5O3 | c = 22.33879 Å |
| Mr = 360.68 | V = 1221.61 Å3 |
| Orthorhombic, P212121 | Z = 4 |
| a = 5.06687 Å | Dx = 1.651 Mg m−3 |
| b = 10.79280 Å |
| x | y | z | Biso*/Beq | ||
| Cl1 | 0.01212 | 0.16968 | 0.02898 | ||
| F2 | 0.90535 | 0.21606 | 0.23899 | ||
| O3 | 0.38561 | 0.02587 | 0.29060 | ||
| O4 | 0.84115 | 0.19497 | 0.38208 | ||
| O5 | 0.75419 | −0.14849 | 0.34117 | ||
| N6 | 0.59832 | 0.02849 | 0.19629 | ||
| N7 | 0.81396 | −0.11960 | 0.14513 | ||
| N8 | 0.31324 | 0.10597 | 0.11693 | ||
| N9 | 0.37245 | −0.00306 | 0.02375 | ||
| N10 | 0.68616 | −0.15566 | 0.00827 | ||
| C11 | 0.49010 | 0.10293 | 0.24534 | ||
| C12 | 0.77245 | 0.11804 | 0.33283 | ||
| C13 | 0.69128 | 0.18783 | 0.27665 | ||
| C14 | 0.52255 | 0.04396 | 0.34742 | ||
| C15 | 0.57085 | −0.08032 | 0.37626 | ||
| C16 | 0.50115 | 0.03082 | 0.13866 | ||
| C17 | 0.78576 | −0.06389 | 0.19766 | ||
| C18 | 0.63647 | −0.06134 | 0.10719 | ||
| C19 | 0.56958 | −0.07502 | 0.04585 | ||
| C20 | 0.26192 | 0.07985 | 0.05972 | ||
| H21 | 0.33140 | 0.15735 | 0.22472 | ||
| H22 | 0.93523 | 0.05413 | 0.32150 | ||
| H23 | 0.59644 | 0.27638 | 0.28803 | ||
| H24 | 0.39549 | 0.09995 | 0.37712 | ||
| H25 | 0.37979 | −0.12899 | 0.38061 | ||
| H26 | 0.64633 | −0.06322 | 0.42197 | ||
| H27 | 0.88790 | −0.08940 | 0.23872 | ||
| H28 | 0.97473 | 0.25980 | 0.36946 | ||
| H29 | 0.75849 | −0.23464 | 0.35654 | ||
| H30 | 0.65698 | −0.14890 | −0.03741 | ||
| H31 | 0.85246 | −0.20128 | 0.02116 |
| D—H···A | D—H | H···A | D···A | D—H···A |
| O4—H28···N7i | 1.01 | 1.72 | 2.726 | 173 |
| O5—H29···N8ii | 0.99 | 1.86 | 2.831 | 167 |
| N10—H30···O4iii | 1.03 | 1.87 | 2.854 | 159 |
| N10—H31···N10iv | 1.02 | 2.38 | 3.271 | 145 |
| C11—H21···F2v | 1.10 | 2.27 | 3.208 | 142 |
| C11—H21···O5vi | 1.10 | 2.60 | 3.531 | 142 |
| C12—H22···O3vii | 1.10 | 2.40 | 3.396 | 149 |
| C15—H26···Cl1viii | 1.11 | 2.77 | 3.570 | 129 |
| C17—H27···F2ix | 1.09 | 2.40 | 3.177 | 127 |
| Symmetry codes: (i) −x+2, y+1/2, −z+1/2; (ii) −x+1, y−1/2, −z+1/2; (iii) −x+3/2, −y, z−1/2; (iv) x+1/2, −y−1/2, −z; (v) x−1, y, z; (vi) −x+1, y+1/2, −z+1/2; (vii) x+1, y, z; (viii) −x+1/2, −y, z+1/2; (ix) −x+2, y−1/2, −z+1/2. |
Acknowledgements
Use of the Advanced Photon Source at Argonne National Laboratory was supported by the U. S. Department of Energy, Office of Science, Office of Basic Energy Sciences, under Contract No. DE-AC02–06CH11357. We thank Saul Lapidus for his assistance in the data collection. We also thank the ICDD team – Megan Rost, Steve Trimble, and Dave Bohnenberger – for their contribution to research, sample preparation, and in-house XRD data collection and verification.
Funding information
Funding for this research was provided by: International Centre for Diffraction Data (grant No. 09-03).
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