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Single-crystal X-ray and neutron powder diffraction investigation of the phase transition in tetra­chloro­benzene

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aDepartment of Chemistry, University College London, 20 Gordon Street, London WC1H 0AJ, England, and bISIS Facility, CCLRC Rutherford Appleton Laboratory, Chilton, Didcot OX11 0QX, England
*Correspondence e-mail: sarah.barnett@ucl.ac.uk

(Received 19 October 2005; accepted 15 December 2005)

The polymorphic phase transition of 1,2,4,5-tetrachlorobenzene (TCB) has been investigated using neutron powder diffraction and single-crystal X-ray diffraction. The diffraction experiments show a reversible phase change that occurs as a function of temperature with no apparent loss of sample quality on transition between the two phases. Neutron powder diffraction gives detailed information on the molecular structural changes and lattice parameters from 2 K to room temperature. The structure of the low-temperature form has been elucidated for the first time using single-crystal X-ray diffraction. Comparison of the α and β structures show that they are both based on the same sheet motif, with the differences between the two being very subtle, except in terms of crystal symmetry. Detailed analysis of the structures revealed the changes required for inter-conversion. A computational polymorph search showed that these two sheet structures are more thermodynamically stable than alternative herringbone-type structures.

1. Introduction

Polymorphism, the ability of a compound to crystallize in more than one crystal structure, is a topic of great interest for both academic research and many industries as it has the potential to significantly affect the physical properties of the compound (Bernstein, 2002[Bernstein, J. (2002). Polymorphism in Molecular Crystals. Oxford: Clarendon Press.]). A detailed analysis of the different polymorphic forms adopted by a compound can yield a structural basis for these physical property differences, which often have important ramifications; indeed, there are many documented cases where production of (or transition to) a polymorph other than that desired has led to severe problems in the manufacture or use of particular compounds (Chemburkar et al., 2000[Chemburkar, S. R., Bauer, J., Deming, K., Spiwek, H., Patel, K., Morris, J., Henry, R., Spanton, S., Dziki, W., Porter, W., Quick, J., Bauer, P., Donaubauer, J., Narayanan, B. A., Soldani, M., Riley, D. & McFarland, K. (2000). Org. Process Res. Dev. 4, 413-417.]). The field of crystal structure prediction aims to allow many of these problems to be anticipated in advance (Price, 2004[Price, S. L. (2004). Adv. Drug Delivery Rev. 56, 301-319.]), particularly by identifying cases where there is a possibility of finding a structure that is more stable than the known forms (Jetti et al., 2003[Jetti, R. K. R., Boese, R., Sarma, J. A. R. P., Reddy, L. S., Vishweshwar, P. & Desiraju, D. R. (2003). Angew. Chem. Int. Ed. 42, 1963-1967.]).

Of particular interest are compounds with polymorphic forms that exhibit a phase transition on changing environmental conditions, e.g. temperature, pressure etc.; the relationship between the two forms must be such that they can interconvert without the need to pass through a different physical state. Tetrachlorobenzene (TCB) is one such compound; the low-temperature α form transforms upon warming to the room-temperature β form. Although the β form has been studied and the structure determined (Herbstein, 1965[Herbstein, F. H. (1965). Acta Cryst. 18, 997-1000.]; Anderson et al., 1991[Anderson, D. G., Blake, A. J., Blom, R., Cradock, S. & Rankin, D. W. H. (1991). Acta Chem. Scand. 45, 158-164.]), only the cell dimensions of the α form had been reported prior to this work and the similarity in the cell dimensions of both forms suggested that the structures are closely related (Herbstein, 1965[Herbstein, F. H. (1965). Acta Cryst. 18, 997-1000.]; Halac et al., 1977[Halac, E. B., Burgos, E. M., Bonadeo, H. E. & D'Alessio, A. (1977). Acta Cryst. A33, 86-89.]).

It is comparatively rare to be able to observe solid-to-solid phase transitions in a single-crystal sample without an accompanying change to a polycrystalline state. Accordingly, a study of the phase transition in TCB as a function of temperature has been performed using both neutron powder diffraction and single-crystal X-ray diffraction.

2. Experimental

1,2,4,5-Tetrachlorobenzene (C6H2Cl4) was purchased from Aldrich Chemicals and recrystallized from a range of solvents using various methods (see supplementary material1). The crystals obtained were predominantly colourless needles and laths. Deuterated tetrachlorobenzene (C6D2Cl4) was purchased from QMX and used for neutron powder diffraction studies without further purification.

2.1. Single-crystal X-ray diffraction

All single-crystal X-ray experiments were performed on a Bruker AXS SMART APEX CCD detector diffractometer equipped with a Bruker AXS Kryoflex open-flow cryostat [graphite-monochromated Mo Kα radiation (λ = 0.71073 Å); ω scans]. Other details of crystal data, data collection and processing are given in Table 1[link] and the supplementary material .

Table 1
Crystal data for the long neutron powder data collections (2, 150, 200 and 295 K) and the single-crystal X-ray data collections

Note: the non-standard setting has been used for the α phase to allow a direct comparison to the β phase; published X-ray data for the β phase at 173 K included for reference (Anderson et al., 1991[Anderson, D. G., Blake, A. J., Blom, R., Cradock, S. & Rankin, D. W. H. (1991). Acta Chem. Scand. 45, 158-164.]).

  X-ray Mo Kα Neutron TOF Neutron TOF Neutron TOF Neutron TOF X-ray Mo Kα
Crystal data
Temperature (K) 150 2 150 200 295 173
Phase α α α (31%) β (69%) β β β
Formula, weight C6H2Cl4, 215.88 C6D2Cl4, 217.88 C6D2Cl4, 217.88 C6D2Cl4, 217.88 C6D2Cl4, 217.88 C6H2Cl4, 215.88
Sample size 0.11 × 0.08 × 0.04 See 150 K 18 × 22 × 5 mm slab-can See 150 K See 150 K 0.75 × 0.5 × 0.4
Crystal system Triclinic Triclinic Triclinic Monoclinic Monoclinic Monoclinic Monoclinic
Space group [P\overline 1] [P\overline 1] [P\overline 1] P21/n P21/n P21/n P21/n
a (Å) 3.8016 (5) 3.76062 (4) 3.7990 (1) 3.78988 (4) 3.81117 (4) 3.85595 (5) 3.7956 (12)
b (Å) 10.6369 (15) 10.58794 (5) 10.6258 (1) 10.50328 (5) 10.53867 (4) 10.61473 (6) 10.5175 (19)
c (Å) 9.4866 (13) 9.44562 (3) 9.47939 (7) 9.56244 (4) 9.57198 (3) 9.59283 (4) 9.5648 (13)
α (°) 92.072 (2) 92.4066 (4) 91.9780 (9) 90.0 90.0 90.0 90.0
β (°) 98.966 (2) 98.6978 (6) 99.058 (2) 99.7184 (6) 99.7088 (5) 99.6884 (7) 99.723
γ (°) 96.520 (2) 97.5893 (6) 96.234 (2) 90.0 90.0 90.0 90.0
Volume (Å3) 375.91 (9) 367.779 (5) 375.13 (1) 375.182 (5) 378.949 (4) 387.033 (6) 376.3
Z 2 2 2 2 2 2 2
Z 2 × 0.5 2 × 0.5 2 × 0.5 0.5 0.5 0.5 0.5
Reflections/unique 6306/5690 1160/1033
wR2 (all data) 0.0990 0.0567
Final R1 [F2 > 2σ(F)] 0.0348 0.0374
wRp; Rexp 0.067; 0.057   0.046; 0.039 0.053; 0.045 0.051; 0.043
g.o.f 1.027 1.315   1.475 1.261 1.216 1.266

Data were collected on a crystal at 200 K, which indexed to be the β form. The crystal was then cooled slowly to 150 K and, somewhat surprisingly, remained intact through the phase transition to the α form. It was evident, through the use of RLATT (Bruker AXS Inc., 2000[Bruker AXS Inc. (2000). Gemini, Version 1.02; RLATT, Version 3.00. Bruker AXS Inc., Madison, Wisconsin, USA.]), that the crystal was twinned (non-merohedral) both before and after the phase transition. GEMINI (Bruker AXS Inc., 2000[Bruker AXS Inc. (2000). Gemini, Version 1.02; RLATT, Version 3.00. Bruker AXS Inc., Madison, Wisconsin, USA.]) was used to index the data and implied that there were two, approximately equal, components. The 150 K data collected for the α form were integrated twice using each orientation matrix and TWINHKL, within GEMINI, was used to write two data files, one containing only non-overlapping data for one component and one containing all data derived from one domain. The single-crystal structure was solved by direct methods using SHELXS97 (Sheldrick, 1997[Sheldrick, G. M. (1997). SHELXS97 and SHELXL97. University of Göttingen, Germany.]) on just a single component and all non-H atoms were located using subsequent difference-Fourier methods in SHELXL97 (Sheldrick, 1997[Sheldrick, G. M. (1997). SHELXS97 and SHELXL97. University of Göttingen, Germany.]). H atoms were placed in calculated positions and thereafter allowed to ride on their parent atoms. However, the data completeness was only 80.4% so the latter data file was used (98.7%). The twin components were related by the twin law (−1 0 −0.08/0 −1 −0.06/0 0 1) and were in the ratio 30:70.

Several other crystals were cooled slowly (1–2 K steps) from 200 to 150 K and a single frame collected at the diffractometer zero position for each temperature in order to observe the range of temperatures over which the phase transition occurred. Once the phase transition appeared complete, the crystal sample was slowly warmed back to 200 K. Unit-cell dimensions were determined at 200 K, both before and after the phase transition, as well as at 150 K, to identify which phases were present.

2.2. Neutron powder diffraction

Neutron powder diffraction experiments were carried out on the HRPD instrument at the ISIS Facility of the CCLRC Rutherford Appleton Laboratory, Oxfordshire, England.

A perdeuterated sample (ca 1 g) of the β phase of TCB was placed in a 5 mm flat vanadium can, cooled through the phase transition to give the α form, and a long data collection (ca 4 h) was carried out at 2 K to provide data suitable for structure refinement. The sample was then warmed in 2 K steps with a short (10 min) data collection at each step; transformation from α to β was observed over the temperature range 154–182 K. At 295 K, another long data collection (ca 5½ h) was carried out before the sample was cooled back down to the region of the phase transition and further long data collections carried out at 200 K and 150 K (ca 5½ and 8 h, respectively). The sample exhibited significant hysteresis and the transformation back to the α form was incomplete by 150 K, with the result that the 150 K data represents a mixed phase.

Initial structures were taken from the relevant single-crystal X-ray models and structure refinement carried out using a restrained Rietveld method (Rietveld, 1969[Rietveld, H. M. (1969). J. Appl. Cryst. 2, 65-71.]) as implemented in TOPAS (Coelho, 2003[Coelho, A. A. (2003). J. Appl. Cryst. 36, 86-95.]). In the full structural refinements (i.e. the long data collections) atomic coordinates were refined (subject to a series of geometric restraints) along with the lattice constants, background, peak shape and preferred orientation parameters. In the case of the 150 K data, the α:β phase ratio was also refined, but the coordinates of the α phase were constrained as a rigid body that was free to rotate. All atoms were refined isotropically, with all atoms of the same type (within a single phase and refinement) constrained to have equal Biso values.

For the refinements against the data from the short data collections (warming cycle), only the lattice parameters, background, peak-shape parameters and, where appropriate, α:β phase ratio were refined. The atomic coordinates were taken from either the 2 K (α phase), 295 K (β phase) or the 150 K (mixed phase) refinement.

2.3. Structure prediction calculations

A gas-phase model for the tetrachlorobenzene molecule was obtained by optimization of the MP2/6-31G** energy using the program GAUSSIAN98 (Frisch et al., 1998[Frisch, M. J. et al. (1998). GAUSSIAN98, Revision A.9. Gaussian, Inc., Pittsburgh, PA, USA.]). The corresponding wavefunction was also calculated for the X-ray determined molecular structures, with the C—H bond length elongated to the standard neutron value of 1.081 Å (Allen et al., 1987[Allen, F. H., Kennard, O. & Watson, D. G. (1987). J. Chem. Soc. Perkin Trans. 2, pp. S1-S18.]). A distributed multipole analysis (DMA; Stone & Alderton, 1985[Stone, A. J. & Alderton, M. (1985). Mol. Phys. 56, 1047-1064.]) of the ab initio charge density of the molecule was performed to provide an accurate description of the electrostatic contribution to the lattice energy in the rigid-molecule crystal structure modeling. This atomic multipolar electrostatic model automatically represents the electrostatic effects of lone pair and π electron density (Price, 1996[Price, S. L. (1996). J. Chem Soc. Faraday Trans. 92, 2997-3008.]).

However, it has been observed that the crystal packing of chlorinated organic molecules, which results in an anisotropic van der Waals radius for Cl, does not only arise from the anisotropy in the electrostatic interaction, but also from the effect of lone-pair density giving an anisotropic repulsive wall (Price et al., 1994[Price, S. L., Stone, A. J., Lucas, J., Rowland, R. S. & Thornley, A. E. (1994). J. Am. Chem. Soc. 116, 4910-4918.]). Thus, a non-empirical model potential developed specifically for the chlorobenzene crystal structures (Day & Price, 2003[Day, G. M. & Price, S. L. (2003). J. Am. Chem. Soc. 125, 16434-16443.]), which is able to reproduce a wide range of the properties of the known chlorobenzenes crystal structures, was used.

The hypothetical crystal structures for tetrachlorobenzene were generated by MOLPAK (Holden et al., 1993[Holden, J. R., Du, Z. Y. & Ammon, H. L. (1993). J. Comput. Chem. 14, 422-437.]), which performs a systematic grid search on orientations of the rigid central molecule in 29 common coordination geometries of organic molecules, belonging to the space groups P1, [P\overline 1], P21, P21/c, C2, Cc, C2/c, P21212, P212121, Pca21, Pna21, Pbcn and Pbca, with one molecule in the asymmetric unit. Approximately 50 of the densest packings in each coordination type are then used as starting points for lattice energy minimization by DMAREL (Willock et al., 1995[Willock, D. J., Price, S. L., Leslie, M. & Catlow, C. R. A. (1995). J. Comput. Chem. 16, 628-647.]) using the non-empirical atom–atom based model potential.

The second derivative properties of each lattice energy minimum were examined (Day et al., 2001[Day, G. M., Price, S. L. & Leslie, M. (2001). Cryst. Growth Des. 1, 13-26.]) and those that were mechanically unstable were eliminated. The distinct low-energy minima within 20 kJ mol−1 of the global minimum were established by considering the reduced cell parameters (Křivý, 1976[Křivý, I. (1976). Acta Cryst. A32, 297-298.]) using PLATON (Spek, 2003[Spek, A. L. (2003). J. Appl. Cryst. 36, 7-13.]) and clustering the identical structures. As the MOLPAK search only produces structures with one entire molecule in the asymmetric unit of the space groups considered, the crystal structures lying within 5 kJ mol−1 of the global minimum were run through the ADDSYM function of PLATON in order to correct the symmetry for structures where the true Z′ was less than 1 and obtain a list of 17 unique structures.

3. Results and discussion

3.1. Determination of the low-temperature α polymorph

Crystals of TCB, prepared by a variety of crystallization methods using a number of different solvents (see Table 1 of the supplementary material ), tended to be of two types: colourless laths and needles, of which, the laths were better suited to single-crystal X-ray diffraction. A large number of these crystals (both laths and needles) were placed on the diffractometer at 200 K and all, without exception, indexed as the β form. One of the crystals (a 30:70 non-merohedral twinned crystal) was cooled slowly using the Kryoflex in ∼ 2.5 K steps from 200 to 190 K, ∼ 1 K steps to 182 K, 2 K steps to 170 K and 5 K steps to 150 K with image frames collected at each step in the diffractometer zero position. Slight changes, attributable to thermal contraction, were observed between successive images, except between 175 and 172 K where there was a major change in the diffraction pattern due to the transition from the monoclinic β form to the triclinic α form. The structure of the α form was solved on a full data set collected at 150 K.

The α form of TCB crystallizes in the space group [P\overline 1 ] with two half molecules sitting on inversion centres in the asymmetric unit (Fig. 1[link]; see Table 2 of the supplementary material for selected bond lengths and angles). Each molecule is involved in four Cl⋯Cl interactions and two bifurcated hydrogen bonds (see §3.3[link] for full structural analysis and comparison to the β phase) to build up two-dimensional sheets which stack as the [2 0 2] Miller planes, each separated by 3.28 Å (Fig. 2[link]). There are ππ stacking interactions between TCB molecules in adjacent planes (centroid–centroid distance 3.799 Å ≡ length of a axis; offset 1.58 Å). This structure is very similar to that found for the room-temperature β form, since the two polymorphs exhibit isomorphic sheet structures of TCB molecules which stack parallel to the [2 0 2] Miller plane.

[Figure 1]
Figure 1
The numbering scheme used for the α form of 1,2,4,5-tetrachlorobenzene. Displacement ellipsoids drawn at the 50% probability level. Symmetry codes: (i) -x, 1-y, 1-z; (ii) 1-x, -y, -z.
[Figure 2]
Figure 2
The two-dimensional sheet formed by the α form of 1,2,4,5-tetrachlorobenzene viewed perpendicular to the [2 0 2] plane showing the Cl⋯Cl interactions (dashed) and bifurcated hydrogen bonds (dotted). C – shaded; Cl – dotted.

3.2. Structural refinement from neutron powder data

Good agreement was found between the structures obtained from single-crystal X-ray data and those refined from the neutron powder data. For further details of the structures at 2, 150, 200 and 295 K, including CIFs, see the supplementary material . The incomplete phase change seen during the cooling cycle resulted in the co-existence of both phases (31% α, 69% β) in the 150 K `long' data set, presenting the opportunity for direct structural comparison under identical conditions. The change in lattice parameters at the phase transition cancel out in such a way that the change in volume is almost negligible; V(α) = 375.13 (1), V(β) = 375.182 (5) Å3 (see Table 2[link]). The absolute changes in the values of the lattice parameters at the phase transition are very small, with the largest shift in unit-cell axis length being only 0.12 Å (∼ 1%). The only shift of any appreciable size is that of the γ angle, which changes by 6.2°. The phase transition is discussed further in §3.5[link].

Table 2
The effect of the phase transition on the lattice parameters

The absolute change in value from the β to the α phase is given as well as this change as a percentage of the α lattice parameter. The absolute shifts in the lattice parameters are small.

      Lattice parameter shift at phase transition
  α (150 K) β (150 K) Absolute Relative to α phase
a (Å) 3.7990 (1) 3.78988 (4) −0.0091 −0.24%
b (Å) 10.6258 (1) 10.50328 (5) −0.12 −1.2%
c (Å) 9.47939 (7) 9.56244 (3) 0.083 0.88%
α (°) 91.9780 (9) 90.0 −2.0 −2.2%
β (°) 99.058 (2) 99.7184 (6) 0.66 0.67%
γ (°) 96.234 (2) 90.0 −6.2 −6.5%
Volume (Å3) 375.13 (1) 375.182 (5) 0.052 0.014%

3.3. Structural comparison of α and β phases

The two phases of tetrachlorobenzene are remarkably similar in structure, although quite distinct crystallographically. The β form crystallizes in the monoclinic space group P21/n with Z = 2 and Z′ = ½, whereas, the α form crystallizes in [P\overline 1], again with Z = 2, but with two independent half molecules in the asymmetric unit. Both forms are characterized by sheets of tetrachlorobenzene molecules that lie in the [2 0 2] plane with an inter-plane distance of 3.28 Å, and are arranged such that the ring centroids are separated by the length of the a axis. Comparison of an individual sheet from each form reveals very little difference between the two (Fig. 3[link], Table 3[link]) with the molecules within the sheets taking part in an extended series of Cl⋯Cl interactions. Since there are two independent molecules in the asymmetric unit of the α form, there are two crystallographically different sets of Cl⋯Cl interactions compared with just one for the β form. The C—Cl⋯Cl—C interaction is characterized by two unequal C—Cl⋯Cl angles, θ1 and θ2, where θ1 > θ2, and θ1 ≃ 180° and θ2 ≃ 90°. This clearly illustrates the anisotropic charge distribution of the carbon-bound Cl atom (Broder et al., 2000[Broder, C. K., Howard, J. A. K., Keen, D. A., Wilson, C. C., Allen, F. H., Jetti, R. K. R., Nangia, A. & Desiraju, G. R. (2000). Acta Cryst. B56, 1080-1084.]; Price et al., 1994[Price, S. L., Stone, A. J., Lucas, J., Rowland, R. S. & Thornley, A. E. (1994). J. Am. Chem. Soc. 116, 4910-4918.]) (see Table 3[link] for actual values of θ1 and θ2). In both phases the Cl⋯Cl interactions form a tetrameric motif centred about an inversion centre, thus the four Cl atoms of the tetrameric motif are, by definition, planar, with the motifs being more symmetric in the α phase than in the β phase. Both phases also exhibit a bifurcated hydrogen bond (Jeffrey, 1997[Jeffrey, G. A. (1997). An Introduction to Hydrogen Bonding. New York: Oxford University Press.]; Yang & Gellman, 1998[Yang, Y. & Gellman, S. H. (1998). J. Am. Chem. Soc. 120, 9090-9091.]) between the H atom and two Cl atoms on an adjacent molecule. The bifurcated hydrogen bonds in the α phase are more symmetric than the same bonds in the β phase; see Table 3[link] for full details. The combination of the Cl⋯Cl interactions and bifurcated hydrogen bonds results in a very well defined sheet which is retained through the phase transition, with the differences between the polymorphs arising from subtle differences in the way that these sheets stack.

Table 3
Geometry of the tetrameric Cl⋯Cl interaction, and the bifurcated hydrogen bonds

Values taken from the powder data model at 150 K (single-crystal data values are similar).

  Interaction Cl⋯Cl (Å) C—Cl⋯Cl θ1 (°) Cl⋯Cl—C θ2 (°) Internal angle (°)  
α phase Cl5⋯Cl8 3.578 165.41 100.50 Cl5⋯Cl8⋯Cl5 90.69
  Cl8⋯Cl5 3.531 156.39 101.30 Cl8⋯Cl5⋯Cl8 89.31
  Cl6⋯Cl9 3.545 161.45 100.19 Cl6⋯Cl9⋯Cl6 87.57
  Cl9⋯Cl6 3.572 161.84 100.47  Cl9⋯Cl6⋯Cl9 92.43
β phase Cl1⋯Cl2 3.538 164.83 101.63 Cl1⋯Cl2⋯Cl1 93.89
  Cl2⋯Cl1 3.578 151.95 102.65  Cl2⋯Cl1⋯Cl2 86.11
  H⋯Cla (Å) H⋯Clb (Å) C—H⋯Cla (°) C—H⋯Clb (°) Cla⋯H⋯Clb (°)
Bifurcated bond
α phase 2.940 2.909 141.35 144.85 64.41
  2.927 2.896 146.92 144.93 64.73
β phase 2.883 3.011 147.34 143.84 64.99
[Figure 3]
Figure 3
The bond lengths (Å) and angles (°) of the Cl⋯Cl interactions and bifurcated hydrogen bonds found in (a) the α form and (b) the β form.

The orientation of the molecules with respect to the [2 0 2] plane is subtly different between the α form and the β form. This is shown in Figs. 4[link], 5[link] and 6[link]. In both cases the ring centroids lie on the [2 0 2] plane. In the α phase the angle between the mean planes of two adjacent and symmetry-independent tetrachlorobenzene molecules is 6.67° with the angle between the mean planes of each of these molecules and the [2 0 2] plane being 7.71 and 9.73°. In the β phase the angle between the mean planes of the same two adjacent (now symmetry related) tetrachlorobenzene molecules is 13.36° and the angle between each of these planes and the [2 0 2] plane is 10.03°. Although the structures of the individual sheets in both polymorphs are very similar (Fig. 3[link]), their stacking arrangements are significantly different, as can be seen in Figs. 5[link] and 6[link].

[Figure 4]
Figure 4
The distance (Å) and angle (°) between stacked molecules in (a) the α form and (b) the β form, as viewed down the c axis.
[Figure 5]
Figure 5
Overlay of the structures of the α phase (blue) and the β phase (red) as viewed in projection, perpendicular to the b axes.
[Figure 6]
Figure 6
The sheets in the (a) α and (b) β phases viewed in projection, perpendicular to the b axes.

When the sheets are viewed side-by-side perpendicular to the b axes, their undulating nature is clearly apparent. Considering these undulations as waves, the amplitude of the wave is greater in the β than in the α form, in which adjacent waves are also slightly offset. The reduction in the amplitude is associated with an increase in periodicity of the wave, i.e. the b axis increases from 10.50328 (5) Å in the β form to 10.6258 (1) Å in the α form at 150 K. The reduction of the amplitude facilitates movement of adjacent sheets relative to one another, giving rise to an offset in the α form and a change in the α and γ angles associated with the loss of symmetry from P21/n to [P\overline 1].

3.4. Phase transition temperature range

The α:β ratios calculated from the short neutron powder data collections are plotted in Fig. 7[link]. It can be seen that the phase transition occurs smoothly and over a significant time and temperature range. Whilst fully reversible, there is a large hysteresis loop associated with the phase transition; on warming, the phase change occurs between 154 and 182 K, yet on cooling the phase transition is incomplete at 150 K. The phase transition was also observed using single-crystal X-ray diffraction, with the precise temperature range of the transition being sample dependent. On cooling four multi-domain twinned-crystal samples, the α form started to appear between 172 and 170 K with the phase transition complete by 160 K; on warming back up to 200 K, β starts to appear in the temperature range 165–175 K and the transition is complete at 184 K. Interestingly, this transition was only observed in twinned crystals; a non-twinned single-crystal sample of the β phase showed no transition to the α phase in accordance with other observations (Mnyukh, 2001[Mnyukh, Y. (2001). Fundamentals of Solid-State Phase Transitions, Ferromagnetism and Ferroelectricity. Bloomington: 1st Books Library.]). In a two-domain 30:70 twinned crystal the number and size of the domains remained approximately unchanged by the phase transition and the phase change was sharp (175–172 K). A more gradual phase transition was observed in multi-domain twinned crystals. This implies that the domain boundaries are necessary for phase transition.

[Figure 7]
Figure 7
Relative proportion of α to β tetrachlorobenzene as a function of temperature for the warming-cycle data sets.

3.5. Thermal expansion and the phase transition

Fig. 8[link] shows the variation in lattice parameters with temperature observed for the neutron powder data. The overlap between the α and β phase curves (blue and red, respectively) indicates where both phases are present simultaneously in the sample. There is good agreement between the lattice parameters obtained from the short data collections and the long data collections (data points symbolized by circles and diamonds, respectively). The change in volume at the phase transition is negligible; on visual inspection, the rate of thermal expansion in volume appears almost continuous across the phase transition.2 The length of the a axis, which corresponds to the distance between adjacent aromatic ring centroids, also hardly varies at the phase transition, shifting by only 0.0091 Å; however, this shift is significant being greater than 3 times the e.s.d. (0.0001 Å). The b and c axes exhibit a slightly larger shift at the phase transition. The γ angle undergoes the largest shift, 6.2°, at the phase transition; the next largest change is in the α angle. These two changes combined affect the offsetting of the undulating sheets.

[Figure 8]
Figure 8
Lattice parameters of α and β phase tetrachlorobenzene (blue and red, respectively) from 2 to 295 K. Circles represent data from the short data collections (warming cycle) while diamonds represent long data collections (cooling cycle).

3.6. Structural prediction calculations

The search for crystal structures corresponding to the minima in the lattice energy produced approximately 350 mechanically stable structures within 10 kJ mol−1 of the global minimum. The resulting unique structures, within 5 kJ mol−1, are shown in Table 4[link] and Fig. 9[link]. The two lowest energy structures (ah30 and ah57) are essentially identical, indicating a complicated energy surface, and have unit cells corresponding to that of the β form of TCB (transforming ah30 into P21/n gives a unit cell of a = 3.8099, b = 10.6351, c = 9.4764 Å β = 100.78°). After transformation, both these predicted structures are virtually superimposable with the structure obtained from the single-crystal literature. The α form (Z′ = 2 × ½) is not predicted in this search because of limitations in the search method, which mean that structures with Z′ > 1 could not be screened. However, a lattice-energy minimization starting from the α structure gives a minimum that is only slightly (0.75 kJ mol−1) more stable than the β form. There is a significant energy gap of 3 kJ mol−1 between these two structures and the next lowest-energy structure, which indicates that other polymorphs are unlikely to be found. As the known structures are the densest, it is unlikely that high-pressure polymorphs exist, although this does not exclude the possible existence of high-temperature phases, as thermally induced motion could result in an entropic term great enough to overcome this 3 kJ mol−1 gap.

Table 4
A summary of the unique predicted crystal structures lying within 5 kJ mol−1 of the global minimum after correction for missing symmetry

Similar structures are labelled as having the same packing type, where S = sheet and H = herringbone.

Trial Space group Z Z Energy (kJ mol−1) V/Z3) a (Å) b (Å) c (Å) β (°) Packing type
ah30 P21/c 4 ½ −90.994 188.60 3.8099 10.6351 9.5295 102.345 S
ah57 P21/c 4 ½ −90.643 188.69 3.8004 10.5979 9.5915 102.346 S
aq3 Pbca 8 ½ −87.768 188.69 7.5093 9.3902 10.9067 90 H 1
bd28 Pna21 4 1 −87.537 192.54 20.6745 3.7466 9.9427 90 H 2
bd39 Pna21 4 1 −87.511 192.72 20.4510 3.7459 10.0625 90 H 2
aq8 Pbca 8 ½ −87.494 192.43 7.5096 9.4198 10.8813 90 H 1
cc30 Pbca 8 1 −87.442 192.21 9.5096 10.8353 14.9236 90 H 3
bd26 Pna21 4 1 −87.437 192.80 20.3905 3.7455 10.0976 90 H 2
cc41 Pbca 8 1 −87.398 192.25 9.5142 10.8240 14.9347 90 H 3
cc14 Pbca 8 1 −87.305 192.27 9.5423 10.7900 14.9393 90 H 3
cd16 Cmca 16 ¼ −87.119 190.93 12.4230 5.3643 11.4599 90 H 4
ap67 Ibam 16 ¼ −87.097 190.93 11.4604 5.3644 12.4228 90 H 6
aq12 Cmca 16 ¼ −87.025 191.00 12.4256 5.3818 11.4250 90 H 4
ap65 Cmcm 16 ½ −87.023 191.00 12.4256 5.3817 11.4251 90 H 7
cb130 Pbca 8 1 −86.487 192.37 7.5253 9.3480 21.8763 90 H 8
fa52 Cmca 16 1 −86.374 191.35 12.4007 5.4237 22.7600 90 H 5
fa115 Cmca 16 ½ −86.313 191.41 12.4035 5.4424 22.6840 90 H 5
[Figure 9]
Figure 9
Plot of lattice energy against cell volume per molecule for the unique structures within 5 kJ mol−1 of the global minimum denoted by the space group assigned after being run through the ADDSYM function of PLATON. The structures corresponding to the α and β forms using the same computational model are also shown.

4. Conclusions

Below room temperature there are no additional new low-temperature phases that are accessible simply by changing the temperature. The phase transition is observed over a temperature range and the precise values of this temperature range appear to be sample and sample-history dependent. However, all the samples exhibited a hysteresis loop with the phase transition temperature consistently lower on cooling from β to α than on warming from α to β. The short-scan neutron powder diffraction data revealed that the phase transition from α to β is gradual for a powder sample and that a temperature range exists where both phases are simultaneously present. Further single-crystal work proved that a gradual phase transition was observed in multi-domain twinned crystals, whereas, in two-domain twinned crystals the phase transition was much sharper and no phase transition was observed in single-domain (non-twinned) crystals. The three largest shifts in lattice parameter on going from the β to the α form of tetrachlorobenzene can by understood by considering the two phases as stacks of undulating sheets with the changes in lattice parameters occurring as a result of the effect of offsetting these sheets. It is usually expected that there will be a loss of symmetry on cooling and indeed this system goes from P21/n to [P\overline 1] on cooling and, in addition, the number of molecular units in the asymmetric unit doubles. However, internally the α polymorph could be considered as being the more perfect system with less of a tilt between adjacent molecules and more symmetric bifurcated hydrogen bonds and Cl⋯Cl tetramers. The computational search confirms that these two polymorphs are very close in energy, as well as structure, and more stable than other, alternative packings.

Supporting information


Computing details top

Data collection: Bruker SMART for tcb_alpha_150K_X-ray; custom ISIS software for tcb_alpha_2K_neutron_powder, tcb_alpha_150K_neutron, tcb_beta_150K_neutron, tcb_beta_200K_neutron, tcb_beta_295K_neutron. Cell refinement: Bruker SAINT for tcb_alpha_150K_X-ray. Data reduction: Bruker SAINT for tcb_alpha_150K_X-ray; custom ISIS software for tcb_alpha_2K_neutron_powder, tcb_alpha_150K_neutron, tcb_beta_150K_neutron, tcb_beta_200K_neutron, tcb_beta_295K_neutron. Program(s) used to solve structure: SHELXS97 (Sheldrick, 1990) for tcb_alpha_150K_X-ray. Program(s) used to refine structure: SHELXL97 (Sheldrick, 1997) for tcb_alpha_150K_X-ray; Topas v3.1 (Coehlo, 2003) for tcb_alpha_2K_neutron_powder, tcb_alpha_150K_neutron, tcb_beta_150K_neutron, tcb_beta_200K_neutron, tcb_beta_295K_neutron. Molecular graphics: Bruker SHELXTL for tcb_alpha_150K_X-ray. Software used to prepare material for publication: Bruker SHELXTL and local programs for tcb_alpha_150K_X-ray.

Figures top
[Figure 1]
[Figure 2]
[Figure 3]
[Figure 4]
[Figure 5]
[Figure 6]
[Figure 7]
[Figure 8]
[Figure 9]
(tcb_alpha_150K_X-ray) Tetrachlorobenzene - alpha polymorph top
Crystal data top
C6H2Cl4Z = 2
Mr = 215.88F(000) = 212
Triclinic, P1Dx = 1.907 Mg m3
a = 3.8016 (5) ÅMo Kα radiation, λ = 0.71073 Å
b = 10.6369 (15) ÅCell parameters from 2248 reflections
c = 9.4866 (13) Åθ = 2.2–28.2°
α = 92.072 (2)°µ = 1.48 mm1
β = 98.966 (2)°T = 150 K
γ = 96.520 (2)°Block, colourless
V = 375.91 (9) Å30.11 × 0.08 × 0.04 mm
Data collection top
Bruker SMART APEX
diffractometer
5184 reflections with I > 2σ(I)
Radiation source: fine-focus sealed tubeRint = 0.000
Graphite monochromatorθmax = 28.3°, θmin = 1.9°
ω rotation with narrow frames scansh = 55
6306 measured reflectionsk = 1413
5690 independent reflectionsl = 1212
Refinement top
Refinement on F2Primary atom site location: direct methods
Least-squares matrix: fullSecondary atom site location: difference Fourier synthesis
R[F2 > 2σ(F2)] = 0.035Hydrogen site location: geometrically placed
wR(F2) = 0.099Riding model
S = 1.03 w = 1/[σ2(Fo2) + (0.0685P)2]
where P = (Fo2 + 2Fc2)/3
5690 reflections(Δ/σ)max = 0.001
97 parametersΔρmax = 0.43 e Å3
0 restraintsΔρmin = 0.28 e Å3
Crystal data top
C6H2Cl4γ = 96.520 (2)°
Mr = 215.88V = 375.91 (9) Å3
Triclinic, P1Z = 2
a = 3.8016 (5) ÅMo Kα radiation
b = 10.6369 (15) ŵ = 1.48 mm1
c = 9.4866 (13) ÅT = 150 K
α = 92.072 (2)°0.11 × 0.08 × 0.04 mm
β = 98.966 (2)°
Data collection top
Bruker SMART APEX
diffractometer
5184 reflections with I > 2σ(I)
6306 measured reflectionsRint = 0.000
5690 independent reflections
Refinement top
R[F2 > 2σ(F2)] = 0.0350 restraints
wR(F2) = 0.099Riding model
S = 1.03Δρmax = 0.43 e Å3
5690 reflectionsΔρmin = 0.28 e Å3
97 parameters
Special details top

Experimental. It was evident, through the use of RLATT, that the crystal was twinned (non-merohedral). GEMINI was used to index the data and showed that there were two, approximately equal components. The output p4p files for each component were read back into SMART and run through the BRAVAIS and L·S. routines. The data were integrated twice (SAINT) using each orientation matrix and TWINHKL, within the GEMINI suite of programs was used to write HKLF 4 and HKLF 5 SHELX data files. The single-crystal structure was solved using direct methods using SHELXS97 on just a single component and all non-hydrogen atoms were located using subsequent difference-Fourier methods. However, the data completeness was only 80.4% so the HKLF 5 file was used (98.7). SADABS can not be performed in this situation since both programmes require the use of the raw files.

Geometry. All e.s.d.'s (except the e.s.d. in the dihedral angle between two l.s. planes) are estimated using the full covariance matrix. The cell e.s.d.'s are taken into account individually in the estimation of e.s.d.'s in distances, angles and torsion angles; correlations between e.s.d.'s in cell parameters are only used when they are defined by crystal symmetry. An approximate (isotropic) treatment of cell e.s.d.'s is used for estimating e.s.d.'s involving l.s. planes.

Refinement. Refinement of F2 against ALL reflections. The weighted R-factor wR and goodness of fit S are based on F2, conventional R-factors R are based on F, with F set to zero for negative F2. The threshold expression of F2 > σ(F2) is used only for calculating R-factors(gt) etc. and is not relevant to the choice of reflections for refinement. R-factors based on F2 are statistically about twice as large as those based on F, and R- factors based on ALL data will be even larger.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/Ueq
C10.0779 (3)0.46699 (11)0.36615 (13)0.0191 (3)
Cl10.17010 (9)0.42699 (3)0.19905 (3)0.02629 (10)
C20.0160 (3)0.37396 (11)0.46285 (13)0.0187 (3)
Cl20.04035 (9)0.21651 (3)0.41860 (3)0.02707 (10)
C30.0624 (3)0.59324 (11)0.40440 (13)0.0202 (3)
H3A0.10560.65690.33940.024*
C40.4342 (3)0.02926 (11)0.13591 (13)0.0193 (3)
Cl40.34762 (9)0.06363 (3)0.30447 (3)0.02507 (10)
C50.5161 (3)0.12245 (11)0.04347 (13)0.0187 (3)
Cl50.53680 (9)0.27600 (3)0.09527 (3)0.02577 (10)
C60.4184 (3)0.09367 (11)0.09192 (13)0.0203 (3)
H6A0.36290.15760.15460.024*
Atomic displacement parameters (Å2) top
U11U22U33U12U13U23
C10.0169 (6)0.0250 (7)0.0158 (6)0.0025 (5)0.0042 (5)0.0019 (5)
Cl10.0337 (2)0.02838 (19)0.01834 (17)0.00325 (13)0.01025 (14)0.00256 (12)
C20.0172 (6)0.0181 (6)0.0209 (6)0.0038 (4)0.0023 (5)0.0016 (5)
Cl20.0366 (2)0.01932 (18)0.02724 (19)0.00532 (13)0.01054 (15)0.00138 (12)
C30.0203 (7)0.0209 (7)0.0195 (7)0.0014 (5)0.0034 (5)0.0031 (5)
C40.0171 (6)0.0255 (7)0.0154 (6)0.0008 (5)0.0043 (5)0.0016 (5)
Cl40.0328 (2)0.02663 (19)0.01774 (17)0.00383 (13)0.00967 (14)0.00261 (12)
C50.0172 (6)0.0192 (6)0.0195 (6)0.0019 (4)0.0022 (5)0.0021 (5)
Cl50.0341 (2)0.02090 (18)0.02395 (18)0.00593 (13)0.00723 (14)0.00349 (12)
C60.0178 (7)0.0237 (7)0.0194 (6)0.0038 (5)0.0032 (5)0.0028 (5)
Geometric parameters (Å, º) top
C1—C31.3885 (16)C4—C61.3918 (16)
C1—C21.3986 (17)C4—C51.3930 (17)
C1—Cl11.7249 (12)C4—Cl41.7257 (12)
C2—C3i1.3803 (17)C5—C6ii1.3843 (17)
C2—Cl21.7280 (12)C5—Cl51.7293 (12)
C3—C2i1.3803 (17)C6—C5ii1.3843 (17)
C3—H3A0.9500C6—H6A0.9500
C3—C1—C2119.72 (11)C6—C4—C5119.79 (11)
C3—C1—Cl1119.39 (9)C6—C4—Cl4119.06 (9)
C2—C1—Cl1120.89 (9)C5—C4—Cl4121.15 (9)
C3i—C2—C1120.44 (11)C6ii—C5—C4120.46 (11)
C3i—C2—Cl2119.02 (9)C6ii—C5—Cl5118.78 (9)
C1—C2—Cl2120.53 (10)C4—C5—Cl5120.75 (9)
C2i—C3—C1119.84 (11)C5ii—C6—C4119.74 (11)
C2i—C3—H3A120.1C5ii—C6—H6A120.1
C1—C3—H3A120.1C4—C6—H6A120.1
C3—C1—C2—C3i0.4 (2)C6—C4—C5—C6ii0.0 (2)
Cl1—C1—C2—C3i179.12 (10)Cl4—C4—C5—C6ii179.39 (10)
C3—C1—C2—Cl2179.04 (9)C6—C4—C5—Cl5179.90 (9)
Cl1—C1—C2—Cl21.45 (15)Cl4—C4—C5—Cl50.47 (15)
C2—C1—C3—C2i0.4 (2)C5—C4—C6—C5ii0.0 (2)
Cl1—C1—C3—C2i179.13 (10)Cl4—C4—C6—C5ii179.40 (10)
Symmetry codes: (i) x, y+1, z+1; (ii) x+1, y, z.
(tcb_alpha_2K_neutron_powder) 1,2,4,5-tetrachlorobenzene top
Crystal data top
C6Cl4D2V = 367.78 (1) Å3
Mr = 217.88Z = 2
Triclinic, P1Cell parameters included in refinement
Hall symbol: P-1Neutron radiation, λ = ? Å
a = 3.76062 (4) ŵ = 0.05 mm1
b = 10.58794 (5) ÅT = 2 K
c = 9.44562 (3) ÅParticle morphology: Needle
α = 92.4066 (4)°Colourless
β = 98.6978 (6)°flat sheet, 20 × 5 mm
γ = 97.5893 (6)°
Data collection top
HRPD, ISIS
diffractometer
Scan method: Time-of-flight
Radiation source: Pulsed neutron sourceAbsorption correction: empirical (using intensity measurements)
Mu = 0.51cm-1 at 1.8A calculated using custom ISIS software program Arial Mucalc
Specimen mounting: 5mm thick vanadium slab canTmin = ?, Tmax = ?
Data collection mode: transmission
Refinement top
Least-squares matrix: selected elements only58 parameters
Rp = 5.73422 restraints
Rwp = 6.7062 constraints
Rexp = 5.093Weighting scheme based on measured s.u.'s
χ2 = 1.734(Δ/σ)max = 0.001
13190 data pointsBackground function: Chebyshev polynomial
Excluded region(s): excluded short and long TOF regions <35000.0/ms and >118500.0/ms excluded detector bank1 <38000.0/ms and >112000.0/ms excluded detector bank2Preferred orientation correction: A Spherical harmonics correction of intensities for preferred orientation was applied according to Jarvinen (1993). The values for detector banks 1 and 2 are given below: sh_bank1_c00 1 sh_bank1_c20 0.93511 sh_bank1_c21p -0.02035 sh_bank1_c21m -0.05750 sh_bank1_c22p -0.96023 sh_bank1_c22m -0.05035 sh_bank1_c40 -0.01777 sh_bank1_c41p 0.00565 sh_bank1_c41m 0.06480 sh_bank1_c42p -0.58460 sh_bank1_c42m -0.01883 sh_bank1_c43p 0.02527 sh_bank1_c43m 0.05883 sh_bank1_c44p 0.34685 sh_bank1_c44m 0.03998
sh_bank2_c00 1 sh_bank2_c20 0.16065 sh_bank2_c21p -0.08458 sh_bank2_c21m 0.01061 sh_bank2_c22p -0.18564 sh_bank2_c22m -0.04873 sh_bank2_c40 0.06927 sh_bank2_c41p -0.02472 sh_bank2_c41m -0.05697 sh_bank2_c42p 0.32069 sh_bank2_c42m -0.01468 sh_bank2_c43p 0.02034 sh_bank2_c43m -0.01361 sh_bank2_c44p -0.14892 sh_bank2_c44m -0.03418
Profile function: Full Voigt with double exponetial
Crystal data top
C6Cl4D2γ = 97.5893 (6)°
Mr = 217.88V = 367.78 (1) Å3
Triclinic, P1Z = 2
a = 3.76062 (4) ÅNeutron radiation, λ = ? Å
b = 10.58794 (5) ŵ = 0.05 mm1
c = 9.44562 (3) ÅT = 2 K
α = 92.4066 (4)°flat sheet, 20 × 5 mm
β = 98.6978 (6)°
Data collection top
HRPD, ISIS
diffractometer
Scan method: Time-of-flight
Specimen mounting: 5mm thick vanadium slab canAbsorption correction: empirical (using intensity measurements)
Mu = 0.51cm-1 at 1.8A calculated using custom ISIS software program Arial Mucalc
Data collection mode: transmissionTmin = ?, Tmax = ?
Refinement top
Rp = 5.73413190 data points
Rwp = 6.70658 parameters
Rexp = 5.09322 restraints
χ2 = 1.734
Special details top

Experimental. The data were collected on 2 detector banks and refined simultanously:

For simplicity the values given as cif data items all correspond to detector bank1 data. Where these values differ from those for bank2, the values for detector bank2 are given in _special_details text blocks.

Geometry. Bond distances, bond angles, torsion angles were calculated using PLATON (Spek, 2003; program version 280604)

Refinement. For detector bank2: _refine_ls_goodness_of_fit_all 1.150

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/Ueq
C10.0819 (6)0.46665 (11)0.36555 (11)0.49 (4)*
C20.0149 (6)0.37293 (17)0.46264 (13)0.49 (4)*
C30.0658 (8)0.59351 (18)0.40366 (12)0.49 (4)*
Cl10.1732 (6)0.42510 (12)0.19717 (13)0.64 (4)*
Cl20.0503 (6)0.21436 (13)0.42054 (14)0.64 (4)*
H30.1049 (9)0.66473 (18)0.32719 (16)1.30 (5)*
C40.4355 (6)0.02858 (11)0.13704 (11)0.49 (4)*
C50.5085 (7)0.12310 (17)0.04347 (13)0.49 (4)*
C60.4161 (8)0.09291 (18)0.09251 (12)0.49 (4)*
Cl40.3446 (6)0.06415 (12)0.30578 (13)0.64 (4)*
Cl50.5353 (6)0.27670 (13)0.09664 (14)0.64 (4)*
H60.3596 (9)0.16730 (17)0.16542 (19)1.30 (5)*
Geometric parameters (Å, º) top
Cl1—C11.728 (2)Cl4—C41.726 (2)
Cl2—C21.736 (2)Cl5—C51.733 (2)
C1—C21.403 (2)C4—C51.389 (2)
C1—C31.387 (2)C4—C61.378 (2)
C2—C3i1.386 (2)C5—C6ii1.398 (2)
C3—H31.077 (2)C6—H61.088 (3)
Cl1—C1—C2120.63 (11)Cl4—C4—C5120.47 (11)
Cl1—C1—C3119.63 (11)Cl4—C4—C6119.54 (12)
C2—C1—C3119.72 (13)C5—C4—C6119.91 (12)
Cl2—C2—C1120.70 (12)Cl5—C5—C4120.92 (11)
Cl2—C2—C3i118.87 (14)Cl5—C5—C6ii119.05 (15)
C1—C2—C3i120.37 (16)C4—C5—C6ii119.91 (16)
C1—C3—C2i119.90 (15)C4—C6—C5ii120.07 (17)
C1—C3—H3119.62 (17)C4—C6—H6120.19 (16)
H3—C3—C2i120.4 (2)H6—C6—C5ii119.62 (19)
Cl1—C1—C2—Cl24.1 (3)Cl4—C4—C5—Cl53.6 (3)
Cl1—C1—C2—C3i178.6 (2)Cl4—C4—C5—C6ii179.6 (2)
C3—C1—C2—Cl2177.5 (2)C6—C4—C5—Cl5179.9 (2)
C3—C1—C2—C3i0.2 (3)C6—C4—C5—C6ii3.9 (3)
Cl1—C1—C3—C2i178.6 (2)Cl4—C4—C6—C5ii179.6 (2)
C2—C1—C3—C2i0.2 (4)C5—C4—C6—C5ii3.9 (4)
Cl2—C2—C3i—C1i177.6 (2)Cl5—C5—C6ii—C4ii180.0 (2)
C1—C2—C3i—C1i0.2 (4)C4—C5—C6ii—C4ii3.9 (4)
Cl1—C1—C3—H31.3 (4)Cl4—C4—C6—H63.6 (4)
C2—C1—C3—H3177.1 (3)C5—C4—C6—H6179.9 (3)
Cl2—C2—C3i—H3i0.2 (4)Cl5—C5—C6ii—H6ii4.0 (4)
C1—C2—C3i—H3i177.1 (3)C4—C5—C6ii—H6ii179.9 (3)
Symmetry codes: (i) x, y+1, z+1; (ii) x+1, y, z.
(tcb_alpha_150K_neutron) 1,2,4,5-tetrachlorobenzene top
Crystal data top
C6Cl4D2V = 375.13 (1) Å3
Mr = 217.88Z = 2
Triclinic, P1Cell parameters included in refinement
a = 3.7990 (1) ÅNeutron radiation, λ = ? Å
b = 10.6258 (1) ŵ = 0.51 mm1
c = 9.47938 (7) ÅT = 150 K
α = 91.9780 (9)°Particle morphology: Needle
β = 99.058 (2)°Colourless
γ = 96.234 (2)°flat sheet, 20 × 5 mm
Data collection top
HRPD, ISIS
diffractometer
Scan method: Time-of-flight
Radiation source: Pulsed neutron sourceAbsorption correction: empirical (using intensity measurements)
Mu = 0.51cm-1 at 1.8A calculated using custom ISIS software program Arial Mucalc
Specimen mounting: 5mm thick vanadium slab canTmin = ?, Tmax = ?
Data collection mode: transmission
Refinement top
Least-squares matrix: selected elements only27 parameters
Rp = 3.90211 restraints
Rwp = 4.59974 constraints
Rexp = 3.473Weighting scheme based on measured s.u.'s
χ2 = 1.753(Δ/σ)max = 0.001
13321 data pointsBackground function: Chebyshev polynomial
Excluded region(s): excluded short and long TOF regions <35000.0/ms and >118500.0/ms excluded detector bank1 <38000.0/ms and >112000.0/ms excluded detector bank2Preferred orientation correction: A Spherical harmonics correction of intensities for preferred orientation was applied according to Jarvinen (1993). The values for detector banks 1 and 2 are given below: sh_bank1A_c00 1 sh_bank1A_c20 0.99392 sh_bank1A_c21p -0.15008 sh_bank1A_c21m 0.01363 sh_bank1A_c22p -0.98430 sh_bank1A_c22m -0.04091 sh_bank1A_c40 0.12805 sh_bank1A_c41p -0.00510 sh_bank1A_c41m 0.09046 sh_bank1A_c42p -0.71077 sh_bank1A_c42m -0.00005 sh_bank1A_c43p 0.02703 sh_bank1A_c43m 0.08732 sh_bank1A_c44p 0.42495 sh_bank1A_c44m 0.01521
sh_bank2A_c00 1 sh_bank2A_c20 0.13922 sh_bank2A_c21p -0.27165 sh_bank2A_c21m 0.06322 sh_bank2A_c22p -0.15558 sh_bank2A_c22m -0.04354 sh_bank2A_c40 0.04018 sh_bank2A_c41p -0.04492 sh_bank2A_c41m -0.06239 sh_bank2A_c42p 0.23357 sh_bank2A_c42m -0.03792 sh_bank2A_c43p 0.02061 sh_bank2A_c43m 0.02549 sh_bank2A_c44p -0.14546 sh_bank2A_c44m 0.15963
Profile function: Full Voigt with double exponetial
Crystal data top
C6Cl4D2γ = 96.234 (2)°
Mr = 217.88V = 375.13 (1) Å3
Triclinic, P1Z = 2
a = 3.7990 (1) ÅNeutron radiation, λ = ? Å
b = 10.6258 (1) ŵ = 0.51 mm1
c = 9.47938 (7) ÅT = 150 K
α = 91.9780 (9)°flat sheet, 20 × 5 mm
β = 99.058 (2)°
Data collection top
HRPD, ISIS
diffractometer
Scan method: Time-of-flight
Specimen mounting: 5mm thick vanadium slab canAbsorption correction: empirical (using intensity measurements)
Mu = 0.51cm-1 at 1.8A calculated using custom ISIS software program Arial Mucalc
Data collection mode: transmissionTmin = ?, Tmax = ?
Refinement top
Rp = 3.90213321 data points
Rwp = 4.59927 parameters
Rexp = 3.47311 restraints
χ2 = 1.753
Special details top

Experimental. The data were collected on 2 detector banks and refined simultanously:

For simplicity, the values given as cif data items all correspond to detector bank1 data. Where these values differ from those for bank2, the values for detector bank2 are given in _special_details text blocks.

Geometry. Bond distances, bond angles, torsion angles and H-bond geometries were calculated using PLATON (Spek, 2003; program version 280604). A freely rotating z-matrix model has been used to constrain the atomic parameters to geometrically idealized positions.

Refinement. This is a mixed phase data set with contributions from both alpha and beta tetrachlorobenzene. Both phases were refined simultaneously, the information in this data block relates to the alpha phase.

The refined ratio of alpha to beta = 31.0 (2):69.0 (2)

A freely rotating z-matrix model was used to constrain the atomic parameters to geometrically idealized positions.

For detector bank2: _refine_ls_goodness_of_fit_all 1.193

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/UeqOcc. (<1)
C10.0761950.4661580.3660551.88 (5)*0.5
C20.0128270.3733220.4617071.88 (5)*0.5
C30.0633680.5928360.4043481.88 (5)*0.5
Cl10.1708640.4241110.1996352.29 (6)*0.5
Cl20.0287640.2159300.4141302.29 (6)*0.5
H30.1131050.6657030.3292722.73 (12)*0.5
C1i0.0761950.5338420.6339451.88 (5)*0.5
C2i0.0128270.6266780.5382931.88 (5)*0.5
C3i0.0633680.4071640.5956521.88 (5)*0.5
Cl1i0.1708640.5758890.8003652.29 (6)*0.5
Cl2i0.0287640.7840700.5858712.29 (6)*0.5
H3i0.1131050.3342970.6707282.73 (12)*0.5
C40.4292000.0303740.1349951.88 (5)*0.5
C50.5157840.1231220.0435481.88 (5)*0.5
C60.4134170.0927480.0914471.88 (5)*0.5
Cl40.3412360.0681130.3027192.29 (6)*0.5
Cl50.5353940.2760950.0976542.29 (6)*0.5
H60.3454580.1655450.1632232.73 (12)*0.5
C4j0.5708000.0303740.1349951.88 (5)*0.5
C5j0.4842160.1231220.0435481.88 (5)*0.5
C6j0.5865830.0927480.0914471.88 (5)*0.5
Cl4j0.6587640.0681130.3027192.29 (6)*0.5
Cl5j0.4646060.2760950.0976542.29 (6)*0.5
H6j0.6545420.1655450.1632232.73 (12)*0.5
Geometric parameters (Å, º) top
Cl1—C11.7270C3i—H3i1.09
Cl1i—C1i1.7270Cl4—C41.7270
Cl2—C21.7270Cl4j—C4j1.7270
Cl2i—C2i1.7270Cl5—C51.7270
C1—C21.3900Cl5j—C5j1.7270
C1—C31.3900C4—C51.3900
C1i—C2i1.3900C4—C61.3900
C1i—C3i1.3900C4j—C5j1.3900
C2—C3i1.3900C4j—C6j1.3900
C2i—C31.3900C5—C6j1.3900
C3—H31.09C5j—C61.3900
Cl1—C1—C2120.00Cl4—C4—C5120.00
Cl1—C1—C3120.00Cl4—C4—C6120.00
C2—C1—C3120.00C5—C4—C6120.00
Cl1i—C1i—C2i120.00Cl4j—C4j—C5j120.00
Cl1i—C1i—C3i120.00Cl4j—C4j—C6j120.00
C2i—C1i—C3i120.00C5j—C4j—C6j120.00
Cl2—C2—C1120.00Cl5—C5—C4120.00
Cl2—C2—C3i120.00Cl5—C5—C6j120.00
C1—C2—C3i120.00C4—C5—C6j120.00
Cl2i—C2i—C1i120.00Cl5j—C5j—C4j120.00
Cl2i—C2i—C3120.00Cl5j—C5j—C6120.00
C1i—C2i—C3120.00C4j—C5j—C6120.00
C1—C3—C2i120.00C4—C6—C5j120.00
C1i—C3i—C2120.00C4j—C6j—C5120.00
C1—C3—H3120.00C4—C6—H6120.00
C2i—C3—H3120.00C5j—C6—H6120.00
C1i—C3i—H3i120.00C4j—C6j—H6j120.00
C2—C3i—H3i120.00C5—C6j—H6j120.00
Cl1—C1—C2—Cl20.00Cl4—C4—C5—Cl50.02
Cl1—C1—C2—C3i179.98Cl4—C4—C5—C6j179.98
C3—C1—C2—Cl2180.00C6—C4—C5—Cl5180.00
C3—C1—C2—C3i0.00C6—C4—C5—C6j0.00
Cl1—C1—C3—C2i179.98Cl4—C4—C6—C5j180.00
C2—C1—C3—C2i0.00C5—C4—C6—C5j0.00
Cl1i—C1i—C2i—Cl2i0.02Cl4j—C4j—C5j—Cl5j0.00
Cl1i—C1i—C2i—C3180.00Cl4j—C4j—C5j—C6180.00
C3i—C1i—C2i—Cl2i180.00C6j—C4j—C5j—Cl5j180.00
C3i—C1i—C2i—C30.00C6j—C4j—C5j—C60.00
Cl1i—C1i—C3i—C2179.98Cl4j—C4j—C6j—C5180.00
C2i—C1i—C3i—C20.00C5j—C4j—C6j—C50.00
Cl2—C2—C3i—C1i180.00Cl5—C5—C6j—C4j180.00
C1—C2—C3i—C1i0.00C4—C5—C6j—C4j0.00
Cl2i—C2i—C3—C1180.00Cl5j—C5j—C6—C4180.00
C1i—C2i—C3—C10.02C4j—C5j—C6—C40.00
Cl1—C1—C3—H30.00Cl4—C4—C6—H60.00
C2—C1—C3—H3180.00C5—C4—C6—H6180.00
Cl1i—C1i—C3i—H3i0.00Cl4j—C4j—C6j—H6j0.00
C2i—C1i—C3i—H3i180.00C5j—C4j—C6j—H6j180.00
Cl2—C2—C3i—H3i0.00Cl5—C5—C6j—H6j0.00
C1—C2—C3i—H3i180.00C4—C5—C6j—H6j180.00
Cl2i—C2i—C3—H30.00Cl5j—C5j—C6—H60.00
C1i—C2i—C3—H3180.00C4j—C5j—C6—H6180.00
(tcb_beta_150K_neutron) 1,2,4,5-tetrachlorobenzene top
Crystal data top
C6Cl4D2Z = 2
Mr = 217.88Cell parameters included in refinement
Monoclinic, P21/nNeutron radiation, λ = ? Å
a = 3.78988 (4) ŵ = 0.51 mm1
b = 10.50328 (5) ÅT = 150 K
c = 9.56244 (3) ÅParticle morphology: Needle
β = 99.7184 (6)°Colourless
V = 375.18 (1) Å3flat sheet, 20 × 5 mm
Data collection top
HRPD, ISIS
diffractometer
Scan method: Time-of-flight
Radiation source: Pulsed neutron sourceAbsorption correction: empirical (using intensity measurements)
Mu = 0.51cm-1 at 1.8A calculated using custom ISIS software program Arial Mucalc
Specimen mounting: 5mm thick vanadium slab canTmin = ?, Tmax = ?
Data collection mode: transmission
Refinement top
Least-squares matrix: selected elements only37 parameters
Rp = 3.90211 restraints
Rwp = 4.5992 constraints
Rexp = 3.473Weighting scheme based on measured s.u.'s
χ2 = 1.753(Δ/σ)max = 0.001
13321 data pointsBackground function: Chebyshev polynomial
Excluded region(s): excluded short and long TOF regions <35000.0/ms and >118500.0/ms excluded detector bank1 <38000.0/ms and >112000.0/ms excluded detector bank2Preferred orientation correction: A Spherical harmonics correction of intensities for preferred orientation was applied according to Jarvinen (1993). The values for detector banks 1 and 2 are given below: sh_bank1B_c00 1.0 sh_bank1B_c20 -1.73091 sh_bank1B_c22p 0.03352 sh_bank1B_c22m -0.03672 sh_bank1B_c40 1.11655 sh_bank1B_c42p -0.03514 sh_bank1B_c42m 0.31755 sh_bank1B_c44p -0.50088 sh_bank1B_c44m -0.37093 sh_bank1B_c60 -0.04523 sh_bank1B_c62p -0.00397 sh_bank1B_c62m -0.07907 sh_bank1B_c64p 0.33570 sh_bank1B_c64m 0.03907 sh_bank1B_c66p -0.09855 sh_bank1B_c66m -0.09855
sh_bank2B_c00 1.0 sh_bank2B_c20 -0.46561 sh_bank2B_c22p 0.06283 sh_bank2B_c22m 0.08408 sh_bank2B_c40 -0.22025 sh_bank2B_c42p 0.01598 sh_bank2B_c42m 0.30682 sh_bank2B_c44p 0.28186 sh_bank2B_c44m -0.20096 sh_bank2B_c60 -0.00143 sh_bank2B_c62p 0.12395 sh_bank2B_c62m 0.08929 sh_bank2B_c64p 0.09454 sh_bank2B_c64m -0.04423 sh_bank2B_c66p -0.02742 sh_bank2B_c66m -0.02742
Profile function: Full Voigt with double exponetial
Crystal data top
C6Cl4D2V = 375.18 (1) Å3
Mr = 217.88Z = 2
Monoclinic, P21/nNeutron radiation, λ = ? Å
a = 3.78988 (4) ŵ = 0.51 mm1
b = 10.50328 (5) ÅT = 150 K
c = 9.56244 (3) Åflat sheet, 20 × 5 mm
β = 99.7184 (6)°
Data collection top
HRPD, ISIS
diffractometer
Scan method: Time-of-flight
Specimen mounting: 5mm thick vanadium slab canAbsorption correction: empirical (using intensity measurements)
Mu = 0.51cm-1 at 1.8A calculated using custom ISIS software program Arial Mucalc
Data collection mode: transmissionTmin = ?, Tmax = ?
Refinement top
Rp = 3.90213321 data points
Rwp = 4.59937 parameters
Rexp = 3.47311 restraints
χ2 = 1.753
Special details top

Experimental. The data were collected on 2 detector banks and refined simultanously:

For simplicity, the values given as cif data items all correspond to detector bank1 data. Where these values differ from those for bank2, the values for detector bank2 are given in _special_details text blocks.

Geometry. Bond distances, bond angles, torsion angles and H-bond geometries were calculated using PLATON (Spek, 2003; program version 280604)

Refinement. This is a mixed phase data set with contributions from both alpha and beta tetrachlorobenzene. Both phases were refined simultaneously, the information in this data block relates to the alpha phase.

The refined ratio of alpha to beta = 31.0 (2):69.0 (2)

For detector bank2: _refine_ls_goodness_of_fit_all 1.193

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/Ueq
C1b0.0694 (4)0.46706 (9)0.36565 (8)1.73 (2)*
C2b0.0187 (5)0.37303 (12)0.45853 (8)1.73 (2)*
C3b0.0952 (5)0.59312 (13)0.40974 (8)1.73 (2)*
Cl1b0.1517 (5)0.42866 (10)0.19978 (10)2.33 (2)*
Cl2b0.0446 (5)0.21599 (11)0.40673 (10)2.33 (2)*
H1b0.1536 (6)0.66714 (12)0.33803 (13)2.83 (5)*
Geometric parameters (Å, º) top
Cl1b—C1b1.7154 (14)C1b—C3b1.3880 (16)
Cl2b—C2b1.7202 (17)C2b—C3bi1.3858 (14)
C1b—C2b1.4056 (15)C3b—H1b1.0839 (19)
Cl1b—C1b—C2b121.24 (8)C1b—C2b—C3bi120.17 (11)
Cl1b—C1b—C3b119.38 (9)C1b—C3b—C2bi120.40 (11)
C2b—C1b—C3b119.37 (9)C1b—C3b—H1b120.23 (11)
Cl2b—C2b—C1b119.99 (8)H1b—C3b—C2bi119.17 (14)
Cl2b—C2b—C3bi119.82 (11)
Cl1b—C1b—C2b—Cl2b0.2 (2)Cl2b—C2b—C3bi—C1bi178.90 (14)
Cl1b—C1b—C2b—C3bi177.94 (15)C1b—C2b—C3bi—C1bi3.0 (3)
C3b—C1b—C2b—Cl2b178.93 (15)Cl1b—C1b—C3b—H1b3.1 (3)
C3b—C1b—C2b—C3bi3.0 (2)C2b—C1b—C3b—H1b177.8 (2)
Cl1b—C1b—C3b—C2bi177.91 (15)Cl2b—C2b—C3bi—H1bi4.0 (3)
C2b—C1b—C3b—C2bi3.0 (2)C1b—C2b—C3bi—H1bi177.9 (2)
Symmetry code: (i) x, y+1, z+1.
(tcb_beta_200K_neutron) 1,2,4,5-tetrachlorobenzene top
Crystal data top
C6Cl4D2Z = 2
Mr = 217.88Cell parameters included in refinement
Monoclinic, P21/nNeutron radiation, λ = ? Å
a = 3.81117 (4) ŵ = 0.51 mm1
b = 10.53867 (4) ÅT = 200 K
c = 9.57198 (3) ÅParticle morphology: Needle
β = 99.7088 (5)°Colourless
V = 378.95 (1) Å3flat sheet, 20 × 5 mm
Data collection top
HRPD, ISIS
diffractometer
Scan method: Time-of-flight
Radiation source: Pulsed neutron sourceAbsorption correction: empirical (using intensity measurements)
Mu = 0.51cm-1 at 1.8A calculated using custom ISIS software program Arial Mucalc
Specimen mounting: 5mm thick vanadium slab canTmin = ?, Tmax = ?
Data collection mode: transmission
Refinement top
Least-squares matrix: selected elements only38 parameters
Rp = 4.52411 restraints
Rwp = 5.2532 constraints
Rexp = 4.166Weighting scheme based on measured s.u.'s
χ2 = 1.590(Δ/σ)max = 0.001
13154 data pointsBackground function: Chebyshev polynomial
Excluded region(s): excluded short and long TOF regions <34000.0/ms and >118500.0/ms excluded detector bank1 <38000.0/ms and >112000.0/ms excluded detector bank2Preferred orientation correction: A Spherical harmonics correction of intensities for preferred orientation was applied according to Jarvinen (1993). Since the preferred orientation should not change with temperture or time Spherical_Harmonics correction was refined against the 295 and 200K data simultaniously. The values for detector banks 1 and 2 are given below: sh_bank2_c00 1.0 sh_bank2_c20 -0.43133 sh_bank2_c22p 0.10625 sh_bank2_c22m 0.10944 sh_bank2_c40 -0.38252 sh_bank2_c42p 0.01095 sh_bank2_c42m 0.20350 sh_bank2_c44p 0.32761 sh_bank2_c44m -0.27992 sh_bank2_c60 0.00414 sh_bank2_c62p 0.12097 sh_bank2_c62m 0.13430 sh_bank2_c64p 0.04673 sh_bank2_c64m -0.05007 sh_bank2_c66p -0.06163 sh_bank2_c66m -0.06163
sh_bank1_c00 1.0 sh_bank1_c20 -1.90462 sh_bank1_c22p 0.18262 sh_bank1_c22m -0.11960 sh_bank1_c40 1.49040 sh_bank1_c42p -0.07359 sh_bank1_c42m 0.50678 sh_bank1_c44p -0.56228 sh_bank1_c44m -0.63237 sh_bank1_c60 -0.05871 sh_bank1_c62p 0.04756 sh_bank1_c62m -0.19668 sh_bank1_c64p 0.42608 sh_bank1_c64m 0.08896 sh_bank1_c66p -0.13523 sh_bank1_c66m -0.13523
Profile function: Full Voigt with double exponetial
Crystal data top
C6Cl4D2V = 378.95 (1) Å3
Mr = 217.88Z = 2
Monoclinic, P21/nNeutron radiation, λ = ? Å
a = 3.81117 (4) ŵ = 0.51 mm1
b = 10.53867 (4) ÅT = 200 K
c = 9.57198 (3) Åflat sheet, 20 × 5 mm
β = 99.7088 (5)°
Data collection top
HRPD, ISIS
diffractometer
Scan method: Time-of-flight
Specimen mounting: 5mm thick vanadium slab canAbsorption correction: empirical (using intensity measurements)
Mu = 0.51cm-1 at 1.8A calculated using custom ISIS software program Arial Mucalc
Data collection mode: transmissionTmin = ?, Tmax = ?
Refinement top
Rp = 4.52413154 data points
Rwp = 5.25338 parameters
Rexp = 4.16611 restraints
χ2 = 1.590
Special details top

Experimental. The data were collected on 2 detector banks and refined simultanously:

For simplicity, the values given as cif data items all correspond to detector bank1 data. Where these values differ from those for bank2, the values for detector bank2 are given in _special_details text blocks.

Geometry. Bond distances, bond angles, torsion angles and H-bond geometries were calculated using PLATON (Spek, 2003; program version 280604)

Refinement. For detector bank2: _refine_ls_goodness_of_fit_all 1.208

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/Ueq
C10.0651 (4)0.46742 (9)0.36540 (7)2.36 (4)*
C20.0139 (5)0.37337 (11)0.45843 (9)2.36 (4)*
C30.0861 (5)0.59328 (13)0.40957 (9)2.36 (4)*
Cl10.1523 (4)0.42918 (9)0.20027 (10)3.11 (4)*
Cl20.0422 (4)0.21672 (10)0.40643 (9)3.11 (4)*
H10.1512 (6)0.66550 (13)0.33866 (14)3.48 (5)*
Geometric parameters (Å, º) top
Cl1—C11.7171 (13)C1—C31.3904 (16)
Cl2—C21.7224 (15)C2—C3i1.3831 (15)
C1—C21.3987 (15)C3—H11.076 (2)
Cl1—C1—C2121.04 (8)C1—C2—C3i119.93 (11)
Cl1—C1—C3119.58 (8)C1—C3—C2i120.67 (11)
C2—C1—C3119.34 (8)C1—C3—H1119.37 (12)
Cl2—C2—C1120.33 (8)H1—C3—C2i119.93 (14)
Cl2—C2—C3i119.68 (10)
Cl1—C1—C2—Cl22.5 (2)Cl2—C2—C3i—C1i179.97 (14)
Cl1—C1—C2—C3i179.46 (14)C1—C2—C3i—C1i3.0 (3)
C3—C1—C2—Cl2179.91 (13)Cl1—C1—C3—H11.4 (3)
C3—C1—C2—C3i2.9 (2)C2—C1—C3—H1179.0 (2)
Cl1—C1—C3—C2i179.40 (15)Cl2—C2—C3i—H1i2.0 (3)
C2—C1—C3—C2i3.0 (2)C1—C2—C3i—H1i179.0 (2)
Symmetry code: (i) x, y+1, z+1.
(tcb_beta_295K_neutron) 1,2,4,5-tetrachlorobenzene top
Crystal data top
C6Cl4D2Z = 2
Mr = 217.88Cell parameters included in refinement
Monoclinic, P21/nNeutron radiation, λ = ? Å
a = 3.85595 (5) ŵ = 0.51 mm1
b = 10.61473 (6) ÅT = 295 K
c = 9.59283 (4) ÅParticle morphology: Needle
β = 99.6884 (7)°Colourless
V = 387.03 (1) Å3flat sheet, 20 × 5 mm
Data collection top
HRPD, ISIS
diffractometer
Scan method: Time-of-flight
Radiation source: Pulsed neutron sourceAbsorption correction: empirical (using intensity measurements)
Mu = 0.51cm-1 at 1.8A calculated using custom ISIS software program Arial Mucalc
Specimen mounting: 5mm thick vanadium slab canTmin = ?, Tmax = ?
Data collection mode: transmission
Refinement top
Least-squares matrix: selected elements only38 parameters
Rp = 4.31511 restraints
Rwp = 5.0502 constraints
Rexp = 4.138Weighting scheme based on measured s.u.'s
χ2 = 1.488(Δ/σ)max = 0.001
13194 data pointsBackground function: Chebyshev polynomial
Excluded region(s): excluded short and long TOF regions <35000.0/ms and >118500.0/ms excluded detector bank1 <38000.0/ms and >112000.0/ms excluded detector bank2Preferred orientation correction: A Spherical harmonics correction of intensities for preferred orientation was applied according to Jarvinen (1993). Since the preferred orientation should not change with temperture or time Spherical_Harmonics correction was refined against the 295 and 200K data simultaniously. The values for detector banks 1 and 2 are given below: sh_bank1_c00 1.0 sh_bank1_c20 -1.90462 sh_bank1_c22p 0.18262 sh_bank1_c22m -0.11960 sh_bank1_c40 1.49040 sh_bank1_c42p -0.07359 sh_bank1_c42m 0.50678 sh_bank1_c44p -0.56228 sh_bank1_c44m -0.63237 sh_bank1_c60 -0.05871 sh_bank1_c62p 0.04756 sh_bank1_c62m -0.19668 sh_bank1_c64p 0.42608 sh_bank1_c64m 0.08896 sh_bank1_c66p -0.13523 sh_bank1_c66m -0.13523
sh_bank2_c00 1.0 sh_bank2_c20 -0.43133 sh_bank2_c22p 0.10625 sh_bank2_c22m 0.10944 sh_bank2_c40 -0.38252 sh_bank2_c42p 0.01095 sh_bank2_c42m 0.20350 sh_bank2_c44p 0.32761 sh_bank2_c44m -0.27992 sh_bank2_c60 0.00414 sh_bank2_c62p 0.12097 sh_bank2_c62m 0.13430 sh_bank2_c64p 0.04673 sh_bank2_c64m -0.05007 sh_bank2_c66p -0.06163 sh_bank2_c66m -0.06163
Profile function: Full Voigt with double exponetial
Crystal data top
C6Cl4D2V = 387.03 (1) Å3
Mr = 217.88Z = 2
Monoclinic, P21/nNeutron radiation, λ = ? Å
a = 3.85595 (5) ŵ = 0.51 mm1
b = 10.61473 (6) ÅT = 295 K
c = 9.59283 (4) Åflat sheet, 20 × 5 mm
β = 99.6884 (7)°
Data collection top
HRPD, ISIS
diffractometer
Scan method: Time-of-flight
Specimen mounting: 5mm thick vanadium slab canAbsorption correction: empirical (using intensity measurements)
Mu = 0.51cm-1 at 1.8A calculated using custom ISIS software program Arial Mucalc
Data collection mode: transmissionTmin = ?, Tmax = ?
Refinement top
Rp = 4.31513194 data points
Rwp = 5.05038 parameters
Rexp = 4.13811 restraints
χ2 = 1.488
Special details top

Experimental. The data were collected on 2 detector banks and refined simultanously:

For simplicity the values given as cif data items all correspond to detector bank1 data. Where these values differ from those for bank2, the values for detector bank2 are given in _special_details text blocks.

Geometry. Bond distances, bond angles, torsion angles and H-bond geometries were calculated using PLATON (Spek, 2003; program version 280604)

Refinement. For detector bank2: _refine_ls_goodness_of_fit_all 1.138

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/Ueq
C10.0636 (4)0.46829 (10)0.36605 (9)3.78 (5)*
C20.0104 (6)0.37410 (14)0.45951 (10)3.78 (5)*
C30.0843 (6)0.59205 (17)0.41025 (10)3.78 (5)*
Cl10.1550 (6)0.43026 (11)0.20164 (13)5.03 (5)*
Cl20.0356 (6)0.21879 (13)0.40684 (12)5.03 (5)*
H30.1429 (7)0.66426 (18)0.3400 (2)5.56 (7)*
Geometric parameters (Å, º) top
Cl1—C11.721 (2)C1—C31.379 (2)
Cl2—C21.722 (2)C2—C3i1.375 (2)
C1—C21.404 (2)C3—H31.070 (3)
Cl1—C1—C2120.88 (10)C1—C2—C3i119.31 (13)
Cl1—C1—C3119.68 (10)C1—C3—C2i121.22 (14)
C2—C1—C3119.32 (10)C1—C3—H3119.77 (15)
Cl2—C2—C1120.12 (10)H3—C3—C2i118.90 (19)
Cl2—C2—C3i120.44 (13)
Cl1—C1—C2—Cl23.7 (3)Cl2—C2—C3i—C1i179.64 (16)
Cl1—C1—C2—C3i179.63 (17)C1—C2—C3i—C1i4.5 (3)
C3—C1—C2—Cl2179.72 (16)Cl1—C1—C3—H33.4 (3)
C3—C1—C2—C3i4.4 (3)C2—C1—C3—H3179.4 (2)
Cl1—C1—C3—C2i179.49 (17)Cl2—C2—C3i—H3i3.5 (3)
C2—C1—C3—C2i4.5 (3)C1—C2—C3i—H3i179.4 (2)
Symmetry code: (i) x, y+1, z+1.

Experimental details

(tcb_alpha_150K_X-ray)(tcb_alpha_2K_neutron_powder)(tcb_alpha_150K_neutron)(tcb_beta_150K_neutron)
Crystal data
Chemical formulaC6H2Cl4C6Cl4D2C6Cl4D2C6Cl4D2
Mr215.88217.88217.88217.88
Crystal system, space groupTriclinic, P1Triclinic, P1Triclinic, P1Monoclinic, P21/n
Temperature (K)1502150150
a, b, c (Å)3.8016 (5), 10.6369 (15), 9.4866 (13)3.76062 (4), 10.58794 (5), 9.44562 (3)3.7990 (1), 10.6258 (1), 9.47938 (7)3.78988 (4), 10.50328 (5), 9.56244 (3)
α, β, γ (°)92.072 (2), 98.966 (2), 96.520 (2)92.4066 (4), 98.6978 (6), 97.5893 (6)91.9780 (9), 99.058 (2), 96.234 (2)90, 99.7184 (6), 90
V3)375.91 (9)367.78 (1)375.13 (1)375.18 (1)
Z2222
Radiation typeMo KαNeutron, λ = ? ÅNeutron, λ = ? ÅNeutron, λ = ? Å
µ (mm1)1.480.050.510.51
Specimen shape, size (mm)0.11 × 0.08 × 0.04Flat sheet, 20 × 5Flat sheet, 20 × 5Flat sheet, 20 × 5
Data collection
DiffractometerBruker SMART APEX
diffractometer
HRPD, ISIS
diffractometer
HRPD, ISIS
diffractometer
HRPD, ISIS
diffractometer
Specimen mounting5mm thick vanadium slab can5mm thick vanadium slab can5mm thick vanadium slab can
Data collection modeTransmissionTransmissionTransmission
Data collection methodω rotation with narrow frames scansTime-of-flightTime-of-flightTime-of-flight
Absorption correction
No. of measured, independent and
observed [I > 2σ(I)] reflections
6306, 5690, 5184
Rint0.000
θ values (°)θmax = 28.3, θmin = 1.92θmin = ? 2θmax = ? 2θstep = ?2θmin = ? 2θmax = ? 2θstep = ?2θmin = ? 2θmax = ? 2θstep = ?
(sin θ/λ)max1)0.666
Refinement
R factors and goodness of fitR[F2 > 2σ(F2)] = 0.035, wR(F2) = 0.099, S = 1.03Rp = 5.734, Rwp = 6.706, Rexp = 5.093, χ2 = 1.734Rp = 3.902, Rwp = 4.599, Rexp = 3.473, χ2 = 1.753Rp = 3.902, Rwp = 4.599, Rexp = 3.473, χ2 = 1.753
No. of reflections/data points5690131901332113321
No. of parameters97582737
No. of restraints0221111
H-atom treatmentRiding model
Δρmax, Δρmin (e Å3)0.43, 0.28


(tcb_beta_200K_neutron)(tcb_beta_295K_neutron)
Crystal data
Chemical formulaC6Cl4D2C6Cl4D2
Mr217.88217.88
Crystal system, space groupMonoclinic, P21/nMonoclinic, P21/n
Temperature (K)200295
a, b, c (Å)3.81117 (4), 10.53867 (4), 9.57198 (3)3.85595 (5), 10.61473 (6), 9.59283 (4)
α, β, γ (°)90, 99.7088 (5), 9090, 99.6884 (7), 90
V3)378.95 (1)387.03 (1)
Z22
Radiation typeNeutron, λ = ? ÅNeutron, λ = ? Å
µ (mm1)0.510.51
Specimen shape, size (mm)Flat sheet, 20 × 5Flat sheet, 20 × 5
Data collection
DiffractometerHRPD, ISIS
diffractometer
HRPD, ISIS
diffractometer
Specimen mounting5mm thick vanadium slab can5mm thick vanadium slab can
Data collection modeTransmissionTransmission
Data collection methodTime-of-flightTime-of-flight
Absorption correction
No. of measured, independent and
observed [I > 2σ(I)] reflections
Rint
θ values (°)2θmin = ? 2θmax = ? 2θstep = ?2θmin = ? 2θmax = ? 2θstep = ?
(sin θ/λ)max1)
Refinement
R factors and goodness of fitRp = 4.524, Rwp = 5.253, Rexp = 4.166, χ2 = 1.590Rp = 4.315, Rwp = 5.050, Rexp = 4.138, χ2 = 1.488
No. of reflections/data points1315413194
No. of parameters3838
No. of restraints1111
H-atom treatment
Δρmax, Δρmin (e Å3)

Computer programs: Bruker SMART, custom ISIS software, Bruker SAINT, SHELXS97 (Sheldrick, 1990), SHELXL97 (Sheldrick, 1997), Topas v3.1 (Coehlo, 2003), Bruker SHELXTL and local programs.

 

Footnotes

1Supplementary data for this paper are available from the IUCr electronic archives (Reference: SO5001 ). Services for accessing these data are described at the back of the journal.

2Full analysis and fit of these graphs to be published in a separate article.

Acknowledgements

The authors would like to acknowledge the Research Councils UK Basic Technology Programme for supporting `Control and Prediction of the Organic Solid State' (https://www.cposs.org.uk ). Thanks go to Professor S. L. Price (University College London) for helpful discussions, particularly with regards to the structural prediction work.

References

First citationAllen, F. H., Kennard, O. & Watson, D. G. (1987). J. Chem. Soc. Perkin Trans. 2, pp. S1–S18.  CrossRef Google Scholar
First citationAnderson, D. G., Blake, A. J., Blom, R., Cradock, S. & Rankin, D. W. H. (1991). Acta Chem. Scand. 45, 158–164.  CrossRef CAS Google Scholar
First citationBernstein, J. (2002). Polymorphism in Molecular Crystals. Oxford: Clarendon Press.  Google Scholar
First citationBroder, C. K., Howard, J. A. K., Keen, D. A., Wilson, C. C., Allen, F. H., Jetti, R. K. R., Nangia, A. & Desiraju, G. R. (2000). Acta Cryst. B56, 1080–1084.  Web of Science CSD CrossRef CAS IUCr Journals Google Scholar
First citationBruker AXS Inc. (2000). Gemini, Version 1.02; RLATT, Version 3.00. Bruker AXS Inc., Madison, Wisconsin, USA.  Google Scholar
First citationChemburkar, S. R., Bauer, J., Deming, K., Spiwek, H., Patel, K., Morris, J., Henry, R., Spanton, S., Dziki, W., Porter, W., Quick, J., Bauer, P., Donaubauer, J., Narayanan, B. A., Soldani, M., Riley, D. & McFarland, K. (2000). Org. Process Res. Dev. 4, 413–417.  Web of Science CrossRef CAS Google Scholar
First citationCoelho, A. A. (2003). J. Appl. Cryst. 36, 86–95.  Web of Science CrossRef CAS IUCr Journals Google Scholar
First citationDay, G. M. & Price, S. L. (2003). J. Am. Chem. Soc. 125, 16434–16443.  Web of Science CrossRef PubMed CAS Google Scholar
First citationDay, G. M., Price, S. L. & Leslie, M. (2001). Cryst. Growth Des. 1, 13–26.  Web of Science CrossRef CAS Google Scholar
First citationFrisch, M. J. et al. (1998). GAUSSIAN98, Revision A.9. Gaussian, Inc., Pittsburgh, PA, USA.  Google Scholar
First citationHerbstein, F. H. (1965). Acta Cryst. 18, 997–1000.  CSD CrossRef CAS IUCr Journals Web of Science Google Scholar
First citationHalac, E. B., Burgos, E. M., Bonadeo, H. E. & D'Alessio, A. (1977). Acta Cryst. A33, 86–89.  CrossRef CAS IUCr Journals Web of Science Google Scholar
First citationHolden, J. R., Du, Z. Y. & Ammon, H. L. (1993). J. Comput. Chem. 14, 422–437.  CrossRef CAS Web of Science Google Scholar
First citationJeffrey, G. A. (1997). An Introduction to Hydrogen Bonding. New York: Oxford University Press.  Google Scholar
First citationJetti, R. K. R., Boese, R., Sarma, J. A. R. P., Reddy, L. S., Vishweshwar, P. & Desiraju, D. R. (2003). Angew. Chem. Int. Ed. 42, 1963–1967.  Web of Science CSD CrossRef CAS Google Scholar
First citationKřivý, I. (1976). Acta Cryst. A32, 297–298.  CrossRef IUCr Journals Web of Science Google Scholar
First citationMnyukh, Y. (2001). Fundamentals of Solid-State Phase Transitions, Ferromagnetism and Ferroelectricity. Bloomington: 1st Books Library.  Google Scholar
First citationPrice, S. L. (2004). Adv. Drug Delivery Rev. 56, 301–319.  Web of Science CrossRef CAS Google Scholar
First citationPrice, S. L. (1996). J. Chem Soc. Faraday Trans. 92, 2997–3008.  CrossRef CAS Web of Science Google Scholar
First citationPrice, S. L., Stone, A. J., Lucas, J., Rowland, R. S. & Thornley, A. E. (1994). J. Am. Chem. Soc. 116, 4910–4918.  CrossRef CAS Web of Science Google Scholar
First citationRietveld, H. M. (1969). J. Appl. Cryst. 2, 65–71.  CrossRef CAS IUCr Journals Web of Science Google Scholar
First citationSheldrick, G. M. (1997). SHELXS97 and SHELXL97. University of Göttingen, Germany.  Google Scholar
First citationStone, A. J. & Alderton, M. (1985). Mol. Phys. 56, 1047–1064.  CrossRef CAS Web of Science Google Scholar
First citationSpek, A. L. (2003). J. Appl. Cryst. 36, 7–13.  Web of Science CrossRef CAS IUCr Journals Google Scholar
First citationWillock, D. J., Price, S. L., Leslie, M. & Catlow, C. R. A. (1995). J. Comput. Chem. 16, 628–647.  CrossRef CAS Web of Science Google Scholar
First citationYang, Y. & Gellman, S. H. (1998). J. Am. Chem. Soc. 120, 9090–9091.  Web of Science CrossRef CAS Google Scholar

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