3.1. Molecular motion

Motion was characterized using VT SCXRD and observed through disorder of the motion-capable molecule. If disorder is present, the site occupancies of the major and minor sites are quantified. If the site occupancies change with temperature, the motion is dynamic, and if the occupancies remain nearly constant, the disorder is static (Harada & Ogawa, 2001, 2009). The molecules imine-I, azo-I, diolefin-Br, diolefin-I Br and diazo-I exhibited disorder during the variable-temperature experiments. The site occupancies of each orientation were allowed to freely refine in the five compounds, and the sum of the two site occupancies was set to a total of one. VT SCXRD experiments demonstrated that all five compounds undergo dynamic pedal motion as confirmed by changes in the site occupancies as a function of temperature (Table 1). The overall change in the site occupancies between 190 and 290 K ranged from 3 to 27% for the five solids. Imine-I and azo-I undergo dynamic pedal motion over the entire temperature range studied [190–290 K, Figs. 4(a) and 4(b)]. The disorder resolves at 250 K in diolefin-Br and 230 K in diolefin-I Br [Figs. 4(c) and 4(d)]. Diazo-I includes two crystallographically unique molecules. Disorder in one of the two molecules resolves at 250 K, and the second molecule exhibits pedal motion over the entire temperature range [Fig. 4(e)]. There was no evidence of pedal motion in the other 11 structures.

Figure 4 X-ray crystal structures at 290 and 190 K highlighting unresolved or resolved disorder within (a) imine-I, (b) azo-I, (c) diolefin-Br, (d) diolefin-I Br and (e) diazo-I. Disorder is only shown for the bridge groups for clarity.

3.2. Compounds with herringbone crystal packing

In total, 11 of the 16 solids crystallize with the extended packing sustained by herringbone π-stacking. The molecules described below self-assemble into 2D sheets through type-II halogen⋯halogen forces. The sheets assemble into herringbone-packed layers that interact through C—H⋯π interactions, type-I halogen⋯halogen bonds and C—H⋯X forces.

The three single-olefin compounds, olefin-I, olefin-Br and olefin-I Br, are isostructural (IUCr Online Dictionary of Crystallography, 2019) and do not exhibit pedal motion. The molecules self-assemble into 2D sheets, which extend in the bc plane [Figs. 5(a), 5(c) and 5(e)]. The sheets further assemble into layers that stack along the crystallographic a axis [Figs. 5(b), 5(d) and 5(f)].

Figure 5 Single-crystal X-ray structures showing 2D halogen-bonded sheets, layers and TE axes for (a) and (b) olefin-I, (c) and (d) olefin-Br, and (e) and (f) olefin-I Br. Type-II halogen bonds are shown with yellow dashed lines, type-I halogen bonds are shown with blue dashed lines and C—H⋯X forces are shown with green dashed lines. Structures are shown at 290 K for olefin-Br and olefin-I Br, and 270 K for olefin-I (due to poor data quality at 290 K).

Unlike the single motion group olefin series, the single imine and azo compounds are not isostructural within a series. Two of the molecules that undergo dynamic pedal motion, imine-I and azo-I, crystallize in the same space group as the three single-olefin molecules and exhibit crystal packing that is isostructural to the olefins (Fig. 6).

Figure 6 Single-crystal X-ray structures at 290 K showing 2D halogen-bonded sheets, layers and TE axes for (a) and (b) imine-I, and (c) and (d) azo-I. Disorder in the aromatic rings and halogens has been omitted for clarity. Type-II halogen bonds are shown with yellow dashed lines, type-I halogen bonds are shown with blue dashed lines and C—H⋯I forces are shown with green dashed lines.

The three diolefin molecules diolefin-I, diolefin-Br and diolefin-I Br crystallize in the same space group as the molecules above and exhibit isostructural crystal packing. The 2D sheets extend in the bc plane [Figs. 7(a), 7(c) and 7(e)] and further stack into herringbone-packed layers along the crystallographic a axis [Figs. 7(b), 7(d) and 7(f)].

Figure 7 Single-crystal X-ray structures at 290 K showing 2D halogen-bonded sheets, layers and TE axes for (a) and (b) diolefin-I, (c) and (d) diolefin-Br, and (e) and (f) diolefin-I Br. Type-II halogen⋯halogen bonds are shown with yellow dashed lines, type-I bonds are shown with blue dashed lines and C—H⋯X forces are shown with green dashed lines.

The two di­imine compounds di­imine-I and di­imine-Br crystallize in a different space group than all the molecules above; however, the crystal packing is still isostructural. The 2D halogen-bonded sheets self-assemble in the bc plane [Figs. 8(a) and 8(c)] and then stack into herringbone-packed layers along the crystallographic a axis [Figs. 8(b) and 8(d)].

Figure 8 Single-crystal X-ray structures at 290 K, highlighting the 2D halogen-bonded sheets, layers and TE axes for (a) and (b) di­imine-I, and (c) and (d) di­imine-Br. Type-II halogen⋯halogen bonds are shown with yellow dashed lines, type-I bonds are shown with blue dashed lines and C—H⋯X bonds are shown with green dashed lines.

The three diazo molecules are not isostructural within a series. The compound diazo-I, which undergoes pedal motion over the entire temperature range, crystallizes in the same space group as the two di­imine molecules and exhibits crystal packing that is isostructural with all the compounds outlined above [Figs. 9(a) and 9(b)]. Diazo-I contains two crystallographically unique molecules and, as outlined in the molecular motion section, one molecule is fully ordered from 190–250 K and exhibits disorder at 270 and 290 K. The second molecule is disordered at all the temperatures studied; however, between 250 and 270 K the positions of major and minor conformations switch [Figs. 9(c) and 9(d)]. The conformational change is accompanied by a 0.13 Å increase in the b axis between 250 and 270 K, while the β angle decreases by 0.58° and approaches 90° (Table S29).

Figure 9 (a) and (b) Single-crystal X-ray structures at 290 K showing 2D halogen-bonded sheets, herringbone packing and TE axes for diazo-I. Disorder in the aromatic rings has been omitted for clarity. Type-II halogen⋯halogen bonds are shown with yellow dashed lines, type-I bonds are shown with blue dashed lines and C—H⋯X bonds are shown with green dashed lines. (c) and (d) Conformational switch in major sites of diazo-I (bottom molecule) between 270 and 250 K. Only the major sites are shown for both molecules.

3.3. Compounds with face-to-face π-stacked crystal packing

Out of the 16 solids, 5 crystallize with the extended packing sustained by face-to-face π-stacking. The five structures described below also self-assemble into 2D sheets through type-II halogen⋯halogen forces, similar to the structures discussed above. However, the sheets in the structures described below assemble into face-to-face π-stacked layers that interact through C—H⋯X forces, rather than herringbone-packed layers.

The three molecules imine-Br, azo-Br(a) and azo-I Br crystallize in the same space group and exhibit isostructural crystal packing. The 2D sheets extend approximately in the bc plane [Figs. 10(a), 10(c) and 10(e)] and then pack into face-to-face π-stacked layers along the crystallographic a axis [Figs. 10(b), 10(d) and 10(f)]. However, the arrangement of the molecules within the 2D sheets differs from the previous structures. Within the sheet, neighboring halogen-bonded molecules are twisted from planarity by ∼55°, whereas in the all the previously described structures, the molecules are much closer to planarity (deviation by 19–32°).

Figure 10 Single-crystal X-ray structures at 290 K highlighting the 2D halogen-bonded sheets, layered packing and TE axes for (a) and (b) imine-Br, (c) and (d) azo-Br(a), and (e) and (f) azo-I Br. Type-II halogen⋯halogen bonds are shown with yellow dashed lines.

The two diazo compounds diazo-Br and diazo-I Br crystallize in a different space group than imine-Br, azo-Br(a) and azo-I Br; however, all five solids exhibit isostructural crystal packing. Within the 2D sheets, which extend approximately in the bc plane [Figs. 11(a) and 11(c)], the neighboring halogen-bonded molecules are twisted from planarity by ∼54°. The face-to-face layers are further packed along the crystallographic a axis [Figs. 11(b) and 11(d)].

Figure 11 Single-crystal X-ray structures at 290 K highlighting 2D halogen-bonded sheets, layered packing and TE axes for (a) and (b) diazo-Br, and (c) and (d) diazo-I Br. Type-II halogen⋯halogen bonds are shown with yellow dashed lines and C—H⋯X bonds are shown with green dashed lines.

3.4. Influence of packing and motion group on pedal motion

As highlighted above, 5 of the 16 single-component solids undergo pedal motion and all five compounds exhibit herringbone crystal packing. Thus, solid-state packing has a clear influence on motion ability.

In the single motion group series, zero of three olefin molecules, one of three azo structures and one of two imine molecules undergo pedal motion in the solid state. In the double-motion group series, two of three double-olefin molecules, one of three double-azo molecules and zero of two double-imine molecules undergo pedal motion in the solid state. At first glance, the identity of the motion group does not appear to significantly impact the occurrence of pedal motion in these single-component halogenated solids. However, examination of the five solids that undergo motion suggests that the degree of motion is influenced by identity. The overall change of the site occupancy between 290 and 190 K reveals that azo groups undergo larger changes (azo-I = 20%, diazo-I = 27 and 24%), the imine lies in the middle (imine-I = 9%) and the olefins undergo the smallest overall changes (diolefin-Br = 3%, diolefin-I Br = 7%).

The pedal motion behaviors in four of the five solids (imine-I, azo-I, diolefin-I Br and diazo-I) were further analyzed by a van't Hoff plot analysis (Harada & Ogawa, 2004, 2009; Harada et al., 2004b; Vande Velde et al., 2015) (Figs. S57–S60). Analysis for diolefin-Br was not performed because disorder is only present at two temperatures. The natural logarithm of the ratio between occupancies of major and minor sites was plotted against the reciprocal of temperature. For the disordered solids imine-I, azo-I and diolefin-I Br, the plots are linear, so the entropic and enthalpic differences between the two sites remain constant during the temperature range and the pedal motion reaches thermodynamic equilibrium. For one of the two unique molecules in diazo-I, the plot is linear in the lower temperature range from 190 to 250 K. On reaching 270 K, the minor conformation of the molecule switches to the major conformation and remains the major site at 290 K. Nonlinearity in van't Hoff plots has been observed in cases where the enthalpy and entropy are different at high and low temperatures, which can indicate a phase transition (Vande Velde et al., 2011). In diazo-I, the conformational switching of the major and minor sites corresponds to a phase transition and is the cause of nonlinearity.

3.5. Thermal expansion analysis

In order to determine the TE behaviors of these halogenated molecules and the impact of crystal packing and motion on TE, PASCal (Cliffe & Goodwin, 2012) was used to calculate the principal axes (X₁, X₂ and X₃) and TE coefficients (α_X1 and α_X2, α_X3) for each crystal using the VT SCXRD data (Table 2, Figs. S1–S17). The single-crystal data at 290 K for olefin-I were excluded because the crystal began to disintegrate and data quality was low. Since diazo-I undergoes a phase transition, only the VT SCXRD data between 190 and 250 K was used for the TE calculations. The crystal packing of diazo-I at 250 K is shown in Fig. S62, which is identical to the packing at 290 K [Figs. 9(a) and 9(b)]. The principal axes for each solid are highlighted in Figs. 5–11. As a benchmark, a TE coefficient ≥ 100 MK⁻¹ has been termed `colossal' TE (Goodwin et al., 2008).

On average, the solids with herringbone packing exhibit different TE behaviors from the face-to-face packed solids along the X₁ and X₂ axes, while the behavior along the X₃ axis is similar. The herringbone solids undergo minimal TE along the X₁ axis, appreciable PTE along the X₂ axis and colossal PTE along X₃ (average: α_X1 = −2, α_X2 = 73, α_X3 = 124 MK⁻¹). The face-to-face packed solids undergo PTE along the X₁ and X₂ axes and colossal PTE along X₃ (average: α_X1 = 9, α_X2 = 46, α_X3 = 130 MK⁻¹). The key differences in TE behavior of the solids arise from differences in halogen-bond strength, crystal packing and motion occurrence.

For the solids with herringbone crystal packing, the X₁ axis lies along the direction of the 2D halogen-bonded sheet. The X₁ axis corresponds to the crystallographic b axis, and the TE coefficients range from −18 to 24 MK⁻¹ (Table 2). Specifically, the molecules with a single motion group exhibit nearly ZTE or PTE, whereas the molecules with two motion groups all exhibit NTE along X₁. The ZTE in olefin-I and olefin-I Br arises from minimal changes along the crystallographic b axis (in the third decimal place) as a function of temperature (Tables S1, S2, S5 and S6). The solids olefin-Br, imine-I and azo-I undergo slight to moderate PTE along X₁, and the length of the crystallographic b axis increases gradually with increasing temperature in each case. The NTE in diolefin-Br, diolefin-I Br, di­imine-I and di­imine-Br arises from a decrease in the length of the crystallographic b axis as the temperature is increased. For diolefin-I, the length of the b axis also decreases upon heating overall to afford NTE, but there is a slight increase in length between 230 and 250 K (Tables S19 and S20).

The influence of molecular width on TE has been investigated by Saha and coworkers who showed that the direction of longer molecular width experiences less TE (Rather et al., 2019). The direction of longer molecular width contains more covalent bonds and less intermolecular interactions; thus, the covalent bonds within the molecule are stronger and will expand less than noncovalent bonds between molecules. In the herringbone structures, the b axis corresponds to the longest width of the molecules and does indeed exhibit the smallest expansion. Perhaps more interesting is that when comparing the shorter (one motion group) to the longer (two motion group) molecules, the longer molecules exhibit less expansion along X₁.

The intermolecular interactions that contribute to TE along X₁ are primarily type-II halogen⋯halogen bonds (Table S37). In the symmetrical single- and double-olefin molecules, the type-II I⋯I distances increase by 0.03 Å in both olefin-I and diolefin-I, whereas the type-II Br⋯Br bond lengths increase by 0.04 Å in both olefin-Br and diolefin-Br on heating. In the two di­imine compounds, the type-II bond lengths increase on heating by 0.03 Å on average for di­imine-I and 0.04 Å on average for di­imine-Br. The larger increase in the Br⋯Br bond lengths is expected since they are weaker than I⋯I bonds. In imine-I and azo-I, the type-II I⋯I separations increase by ca 0.06 Å on warming. The larger increase in bond length for these iodinated solids could be due to appreciable pedal motion over the entire temperature range, which includes a small repositioning of the iodine atoms. For the unsymmetrical solids, the iodine and bromine atoms sit at nearly identical crystallographic positions with site occupancies of 0.5 and 0.5. This prevented a clear comparison of bond length changes between the symmetrical and unsymmetrical solids because, at any point, the contact could be I⋯I, Br⋯Br or I⋯Br (see Table S37 for all three values). We also calculated the centroid of the I/Br atoms on each side of the type-II bond and measured the distance between the centroids. For olefin-I Br, the centroid separation decreases by 0.01 Å on heating, and the separation increases by 0.03 Å for diolefin-I Br on heating. The type-I halogen⋯halogen interactions also contribute slightly to the expansion along X₁ in the herringbone-packed compounds, and the distances increase by ca 0.03–0.09 Å on warming.

Diazo-I exhibits slightly larger PTE along X₁ than the other herringbone solids, but the temperature range used for the calculation only includes data from 190–250 K due to the conformational change at 270 K. The PTE arises from an increase in the length of the b axis with increasing temperature, the type-II I⋯I bonds increase by an average of 0.02 Å, and the type-I I⋯I bonds increase by 0.05 Å.

In the isostructural molecules that exhibit face-to-face π-stacked crystal packing, imine-Br exhibits ZTE and the other four molecules undergo slight PTE along X₁. The ZTE in imine-Br arises from minimal changes along the crystallographic c axis (in the third decimal place) as a function of temperature (Tables S9 and S10). Unlike the herringbone solids, expansion along X₁ for the face-to-face π-stacked solids encompasses the a and/or c crystallographic axes (Table 2). In all five solids, the direction of the X₁ axis includes the C—H⋯X forces, which increase by ca 0.03–0.06 Å on warming (Table S37). In imine-Br, diazo-Br and diazo-I Br, the π⋯π-stacking interactions also contribute to X₁ and increase by ca 0.05–0.07 Å on warming. In one case, namely azo-I Br, the type-II halogen⋯halogen bonds lie along X₁, akin to the herringbone structures, and the centroid I/Br distance increases by 0.03 Å on heating. The difference in the direction of the X₁ axis and included intermolecular forces for the face-to-face solids with respect to the structure results in larger average TE coefficients compared with the herringbone solids.

The X₂ axis corresponds to the c axis in the herringbone solids and the b axis for the face-to-face π-stacked solids. Importantly, in both the herringbone and the face-to-face π-stacked solids, the direction of X₂ with respect to the structure is nearly identical. The X₂ axis lies along the vertical direction of the 2D halogen-bonded sheet and includes the type-II halogen⋯halogen contacts [Figs. 12(a) and 12(c); Table S38]. The difference in the two structure types arises in the arrangement of neighboring molecules within the 2D sheet. In the herringbone structures, molecules within a sheet are parallel, but lie edge-to-face between the sheets [Fig. 12(b)]. In the face-to-face structures, molecules within a sheet and between sheets are parallel [Fig. 12(d)]. On heating, the solids in the herringbone arrangement twist further from co-planarity, and for solids that undergo pedal motion, the conformational interconversion affects the X₂ axis [Fig. 12(b)]. On the other hand, molecules in the face-to-face structures remain coplanar and do not undergo motion. This structural difference results in a difference in TE behaviors; thus, the solids with herringbone packing exhibit larger PTE along X₂. Additionally, on average, the c-axis length in the herringbone solids experiences a larger increase on heating than the b axis length in the face-to-face π-stacked molecules.

Figure 12 Single-crystal X-ray structures highlighting X2 axes for representative (a) and (b) herringbone structures (imine-I), and (c) and (d) face-to-face π-stacked structures (imine-Br). The X2 planes are shown in red and going into the page.

All 16 solids in the herringbone and face-to-face categories exhibit colossal (Goodwin et al., 2008) PTE along X₃, and on average, the solids exhibit similar TE coefficients (Table 2). The X₃ axis in both types of solids lies along the π-stacking direction. For the herringbone solids, this encompasses the C—H⋯π interactions, whereas in the face-to-face stacked solids, this includes π⋯π interactions. On heating, the C—H⋯π distances increase by ca 0.04–0.05 Å on average in the herringbone solids, whereas the π⋯π distances increase by ca 0.05–0.07 Å on average in the face-to-face stacked solids (Table S39). These differences in interaction type and distance change over the temperature range afford a slightly higher TE average for the face-to-face π-stacked solids. The solid imine-Br exhibits the largest PTE along X₃ (α_X3 = 162 MK⁻¹) due to the largest increase in π⋯π distance (0.07 Å).

The volumetric TE coefficient for all 16 solids is also colossal and ranges from 166 to 212 MK⁻¹. The volume of each crystal increases gradually on warming (Figs. S40–S56) and the volume increases by ca 1.5–2.1% on heating. On average, the solids with herringbone packing exhibit slightly larger volumetric TE (average α_V = 197 MK⁻¹) than the solids with face-to-face π-stacking (average α_V = 187 MK⁻¹), owing to the significantly larger expansion along X₂.

3.6. Unsymmetrical olefins

The unsymmetrical I⋯Br systems were designed to offer an interplay between the symmetrical I⋯I and Br⋯Br solids with regard to bond strength and TE along the halogen-bonding direction. All six olefins crystallized in the herringbone packing motif, and the type-II halogen⋯halogen interactions contribute to TE along the X₁ and X₂ axes. Gratifyingly, the solid olefin-I Br exhibits a TE coefficient between olefin-I and olefin-Br for both α_X1 and α_X2. The solid diolefin-I Br exhibits a TE coefficient between diolefin-I and diolefin-Br for α_X1; however, the TE coefficient of diolefin-I Br along X₂ is within the error of diolefin-Br.