1.1. Description of stabilities

The solid-state phase transformations can be observed using differential scanning calorimetry (DSC). DSC provides phase transition temperatures and enthalpies, although these data have to be taken cum grano salis, since they are influenced by kinetics and by the phase purity of the sample. In particular, a recent study points to the difficulties in assessing the exact temperature of the α to γ transition (Li et al., 2020) because the transition temperature depends on the DSC heating rate. Based on the phase transformations observed during storage of crystals at a range of temperatures, Li et al. propose a transformation temperature of 392 (1) K. The difference in solid state enthalpies between α and γ seems to be temperature independent and amounts to 13.2 (6) J g⁻¹ corresponding to 1.6 (1) kJ mol⁻¹, with the α form being enthalpically the most stable.

Based on the observed phase transformations from DSC, hot-stage microscopy, Raman and PXRD measurements, it appears that at low temperatures, the γ form is the least stable – yet at higher temperatures all other forms – α, β and δ – transform to γ before reaching the melting point (Castro et al., 2010, Cherukuvada et al., 2010). Additionally, already at room temperature the δ form can transform into the α form. The free energy versus temperature diagram in Fig. 2 agrees with these observations. However, several other G–T diagrams could be sketched: in particular, it is difficult to draw any conclusions of the relative stabilities at 0 K for the β form in relation to the α and δ forms. Although the transformation to γ appears to occur at a lower temperature than for α and δ, the β form could be the most stable at 0 K if the G–T line for β is less curved than for the other forms. This would imply that the G–T curve of β would cross the curves of α and δ, implying possible phase transformations – which, however, could be kinetically hindered.

To get an understanding of the different contributions giving rise to a temperature dependence of the relative thermodynamic stabilities of the four polymorphs, it is necessary to obtain an insight into the enthalpic as well as entropic contributions to the free energy, i.e. to calculate G = H − TS, where H is the enthalpy, T is the temperature and S is the entropy. In this work, we use a combination of periodic DFT calculations and X-ray diffraction measurements to obtain an estimate of the free energy G at different temperatures, as outlined below.

1.2. Entropic contribution to thermodynamic stabilities

At absolute zero, a perfect crystal has zero entropy. However, disorder in the crystalline phase may give a contribution to the entropy even at T = 0 K.

It is well known that the γ form of pyrazinamide is disordered (Cherukuvada et al., 2010). The crystal structure shows that 15% of the molecules are rotated (vide infra). On one hand, this disorder gives rise to a small decrease in the enthalpic stability of the crystal, while on the other hand stabilizes the crystal entropically.

Whereas the disorder of the γ form is readily visible in the electron density derived from single-crystal diffraction experiments, we have found it interesting to investigate whether the other polymorphs are disordered in any way. Therefore, we have conducted measurements at 10 K. At this temperature, disorder that is not visible at higher temperatures – i.e. hiding as a contribution to the displacement ellipsoids – can be revealed. At 10 K the intermolecular vibrations are significantly reduced. The disorder will manifest itself as splitting of atomic positions, or as significantly larger ellipsoids than what can be expected to arise from intramolecular motion.

Apart from the disorder, the most substantial contribution to the entropy in the solid state is from the thermal vibrations in the crystal. Vibrational contributions to free energy are demanding to obtain from theoretical calculations for molecular crystals due to high computational costs, and because the accuracy of the calculated low-frequency phonons may be low. Thus, for the pyrazinamide polymorphs we apply a recently developed quantum crystallography method (Genoni et al., 2018), coined Dynamic Quantum Crystallography, of estimating vibrational entropy and enthalpy from frequencies refined against single crystal X-ray diffraction data (Hoser & Madsen, 2016; 2017). We term this refinement a normal-mode refinement (NoMoRe), and in recent years we have explained, validated, and applied this approach to various systems to estimate thermodynamic properties (Hoser et al., 2021; Sovago et al., 2020; Kofoed et al., 2019).

1.3. Enthalpic contribution to thermodynamic stability

While the NoMoRe procedure ensures an estimate of the vibrational entropy and enthalpy, the enthalpic differences due to inter- and intramolecular conformations of the molecules are not considered. In recent years, periodic DFT calculations including an empirical estimate of dispersion interactions have been shown to be able to give reasonable estimates of differences in crystal polymorph enthalpies and has been an important reason for the success of crystal structure prediction (Reilly et al., 2016). However, in our previous work (Wahlberg et al., 2014) we have explored how differences in the crystal geometries of pyrazinamide can lead to rather different DFT-estimated stabilities of the pyrazinamide polymorphs.

In the present contribution, we update that work using new methodology, in particular with respect to the empirical estimates of the dispersion forces. Next, we estimate contributions to the Gibbs free energies that arise from vibrations and disorder and we predict the ordering of stability of polymorphic forms at different temperatures.

2.1. Single-crystal X-ray diffraction

Crystalline pyrazinamide, purchased from Sigma, was used without further purification. The α, β and δ polymorphs were crystallized from the saturated solution by slow evaporation at room temperature. The respective solvents were water, chloro­form and di­chloro­methane, in accordance with the work of Castro et al. (2010). Crystals of the α form were slowly heated in an oven to 160 °C and in what appears to be a single-crystal to single-crystal transformation turned to the γ form.

The diffraction measurements were performed using Bruker/Nonius in-house X-ray diffractometers, and the temperature was controlled by use of nitro­gen and helium open gas-flow systems (from Cryo Industries of America). All data were collected using molybdenum radiation and with area detectors. For each polymorph, data at 10 K and 122 K were collected. The 10 K data were limited to a resolution of maximum sin(θ)/λ = 0.8 Å⁻¹, whereas the 122 K data were obtained to at least sin(θ)/λ = 1.0 Å⁻¹. The data were integrated and reduced using the SAINT program.

For the deposited structures, the software JANA2006 (Petříček et al., 2014) was used for structure solution and refinement. Anisotropic displacement parameters were refined for non-hydrogen atoms. The hydrogen atoms were fixed at calculated positions and refined using the riding model. For the γ polymorph, a rigid-body approach was used for the minor disorder component.

The SHELXL program (Sheldrick, 2015) was used for block-refinement as part of the NoMoRe refinement.

An overview of the crystallographic information can be found in Table 1.

2.2. Theoretical calculations

Periodic ab-initio density functional theory (DFT) calculations were performed for the selected systems using the CRYSTAL17 program (Dovesi et al., 2017).

Electronic energy calculations. Electronic energies were calculated with two different functionals B3LYP (Lee et al., 1988) and PBE0 (Adamo & Barone, 1999) in combination with an D3 empirical dispersion (Grimme et al., 2010) energy correction and with a large pVTZP (Schäfer et al., 1994) basis set with polarization functions. The truncation parameters, TOLINTEG, were set to 7 7 7 7 25 and the shrinking factors in the reciprocal space, SHRINK, were set to 8 and 8.

Moreover, we tried two approaches – full geometry optimization and optimization of atom coordinates only, with cell parameters fixed at those from the 10 K measurements.

Phonon calculations were performed in CRYSTAL17 to provide an ansatz for the Normal Mode Refinements (NoMoRe). The standard 6-31G(d,p) basis set was applied. It has been used extensively and gives reasonable relative stabilities of related systems; it has also been used for the estimation of vibrational frequencies. We optimized the geometry (only the coordinates, starting from the experimental geometry). Subsequently, we calculated the normal modes and their frequencies at the Γ point of the Brillouin zone. The convergence criteria for geometry optimization were set to the default for frequency calculations using the PREOPTGEOM keyword. As we optimized only the coordinates, the frequencies were calculated using the cell parameters from the 122 K XRD measurements. Input for CRYSTAL17 frequency calculations can be easily created using our cif2crystal routine (https://shade.ki.ku.dk/docs/cif2crystal.html).

2.3. The normal-mode refinements (NoMoRe)

We used the nomore.chem.uw.edu.pl web server (a version of the NoMoRe Python program) to conduct refinements against pyrazinamide polymorph X-ray data from 122 K. For α, β and δ we submitted normal-mode vectors and their frequencies obtained from theoretical calculations, structure factor files and input files for SHELXL with a model of the given structure. For each polymorphic form we refined six frequencies, corresponding to the low-energy acoustic and optical phonons, which lead us to reasonable models (with quite low agreement indices (wR²) and anisotropic displacement parameters (ADPs) similar to those from routine SHELXL refinement, see supporting information). The NoMoRe python program was adapted to refine the disordered γ polymorph. During these refinements, the parameters describing the minor disorder component were kept constant. The electron density related to the minor disorder component does not overlap with the density of the major component, and thereby the displacement parameters of the major component appear unaffected by the disorder.

2.4. Evaluation of thermodynamic functions

In the case of all polymorphic forms we used known thermodynamic equations, which we already applied for polymorphs of di­methyl-3,6-di­chloro-2,5-di­hydroxy­terephthalate (Kofoed et al., 2019). For each polymorph the free energy (G) is calculated as it is shown in the following equations:

where H is enthalpy, T is temperature in K and S is entropy. The enthalpic part can be divided into U, crystal packing energy, and a , pressure × volume, term which take into account the expansion of the unit cell with temperature

(where the pΔV term is calculated at a pressure of 1 atm), whereas

E_total is an electronic energy which is accessible from DFT calculations and the contribution from vibrational energy, F_vib is

Where the summation in equation (1) runs over frequencies ν, h is Planck's constant and k is the Boltzmann constant. The first part of the equation is the zero-point energy (ZPE), while the second part is the contribution to enthalpy (Hvib) coming from normal-mode vibrations. In a similar fashion, the vibrational entropy can be obtained by summation over all normal-mode vibrations:

In the case of NoMoRe all the frequencies obtained from the calculations in CRYSTAL17 (and for which a subset was subsequently refined against the diffraction data) were used in order to obtain full vibrational contributions to free energy.

For the γ form, we additionally took into account the entropy arising from disorder, as outlined below.

2.5. Entropy of mixing for γ polymorphic form

Disorder can stabilize the γ pyrazinamide structure by increasing the entropy. We estimate these entropy contributions by calculating the entropy of mixing.

where x₁ and x₂ are the experimentally observed occupancies (0.15 and 0.85).

3.1. Structures and intermolecular interaction description

The structures of the pyrazinamide polymorphs have already been described and are well known. The data for all pyrazinamide polymorphs obtained in this study at 122 K are of a high-resolution [sin(θ)/λ > 1.0 Å⁻¹], giving more confidence in the atomic positions and the description of disorder than previous studies. Previously, a comparable resolution data of sin(θ)/λ > 1.0 Å⁻¹ have only been reported for α and β polymorphs (Rajalakshmi et al., 2014; Jarzembska et al., 2014). The data obtained at 10 K are of a slightly lower resolution [sin(θ)/λ ≃ 0.8 Å⁻¹], simply due to experimental limitations where the cost of helium sets a limit to the experiment time. However, the displacement parameters of the α, β and δ polymorphs derived from the 10 K data indicates that there is no disorder in these systems. The γ form is thereby the only form where a more advanced model is needed for the calculation of the enthalpic contribution to the free energy via periodic DFT calculations.

Comparing energy frameworks (Turner et al., 2015, Spackman et al., 2021) generated for pyrazinamide polymorphs (Fig. 3) we immediately see that in the α, β and δ polymorphs dimers are formed by pyrazinamide molecules via the hydrogen bonding between amide groups. For those structures, this is the strongest interaction. Such dimers are stabilized by other weaker - mostly dispersive - interactions. The γ form is a remarkable exception – here, neighboring pyrazinamide molecules form chains via hydrogen bonding interactions of amide groups with nitro­gen from the aromatic ring. Furthermore, such chains are stabilized by dispersive interactions (see supporting materials). Therefore, proper dispersion corrections are crucial for theoretical calculations for this system.

Figure 3 Energy frameworks generated for pyrazinamide polymorphs [CrystalExplorer (Spackman et al., 2021), B3LYP level of theory].

Comparison of anisotropic displacement parameters (ADPs) reveals that ADPs for the α and γ forms are significantly larger than those for the other polymorphic forms (Fig. 4). In the case of the α form this observation can be rationalized by comparison of unit-cell volumes and densities for different polymorphic forms – the α form has significantly higher cell volume and lower density than the other polymorphic forms – thus, the atoms have more space to vibrate and in consequence the ADPs are larger.

Figure 4 Visual comparison of non-hydrogen ADPs from 122 K. Ellipsoids are depicted at the 90% probability level.

Large ADPs for the α and γ forms are a hint that the vibrational entropy can give important contributions to the relative stability of polymorphic systems. However, the system with the largest ADPs does not always have the largest entropy, because the intramolecular vibrations can play a significant role, as we have demonstrated previously (Kofoed et al., 2019).

3.2. On the disorder of γ polymorph

The γ polymorph is statically disordered. This has been observed also in previous studies (Wahlberg et al., 2014). Evident electron density maxima showing presence of a second disorder component are present in the Fourier difference maps. In Fig. 5 the asymmetric unit is depicted showing the major disorder component along with the backbone of the pyrazinamide molecule related to the minor disorder component. Two orientations of the minor site are possible.

Figure 5 Asymmetric unit of the pyrazinamide γ polymorph showing the backbone of the minor disorder component and two possible orientations of the molecule that may occupy the disordered site.

Determining which of the orientations occupy the minor disordered site is not straightforward. Furthermore, both presented orientations might be present resulting in three disordered components in total. We did refinements with either the A or B disorder components present, and found that the R₁ value was more than 1% lower when component A was present. In both cases, the disorder component ratio was refined to approximately 85:15. It is consistent with a structure model reported earlier, where the disorder ratio is 87:13 (Cherukuvada et al., 2010). There, the minor disorder component is also considered in orientation A.

Analysis of hydrogen bonding also hints that a pyrazinamide molecule with orientation A would result in an energetically more favorable state. In Fig. 6(a), a structural motif as formed by the major component is depicted also indicating the hydrogen bonding. There are four (two unique) hydrogen bonds associated with each molecule. Expansion of the hydrogen bond network results in a layer. If one molecule is replaced with the minor disorder component in the A orientation, then four other hydrogen bonds are possible [see Fig. 6(b)]. However, if a local structure with a minor disorder component in its B orientation is considered, then only one rather long and thus inefficient hydrogen bond is formed with the molecules of the major disorder component [see Fig. 6(c)].

Figure 6 Local structures of (a) solely the major disorder component; (b) the major disorder component and one molecule of the minor component – orientation A; (c) the major disorder component and one molecule of the minor component – orientation B. D⋯A distances of possible hydrogen bonds are shown as solid lines, while dashed lines indicate D⋯H.

3.3. Lattice and total electronic energies

The lattice energies for pyrazinamide polymorphs were already calculated using various different methods (Wahlberg et al., 2014). It was found that differences in lattice energies are extremely small and the stability order of the pyrazinamide polymorphs can be reverted by applying a slightly different calculation scheme (e.g. by changing a basis set or by small changes of a unit cell).

Herein we conducted once again total and lattice energy calculations at different levels of theory and this time with the D3 dispersion correction. The lowest electronic energy we obtained for the β form, whereas the highest for the α form (see Table 2). As the high total electronic energy for the α form is in a good agreement with experimental results, such low energy calculated for the β form is surprising – according to the experimental results the most stable form at low temperature should be the δ form. Wahlberg et al. (2014) managed to calculate energies which reproduce experimental stability order by means of theoretical computations with fixed unit-cell parameters at 122 K, with large modified VZP basis set and Grimme dispersion correction. In our case, although we applied a TZVP basis set and D3 dispersion correction, the β form exhibits lower total energy than the δ form.

Regarding the γ form of pyrazinamide, in Table 2 we present results of calculations which we obtained for the main component, i.e. without disorder. In such a case, the γ polymorph have almost equal energy to the δ form. In the real crystal structure, we do observe disorder and thereby the lattice/total electronic energy for the disordered structure is slightly higher than for the hypothetical non-disordered crystal. This destabilization is recompensed at higher temperatures by contributions from the configurational entropy.

In the work of Wahlberg et al. (2014), a 2 × 1 × 1 supercell with P1 symmetry was constructed, and one out of eight molecules were flipped to reflect the disorder observed experimentally. In the present case, we have constructed a somewhat larger supercell (2 × 3 × 2) to ensure that the flipped molecules are isolated from each other, in this supercell one out of 24 molecules was flipped. The electronic energy calculated in that manner (B3LYPD3, cell fixed and coordinates optimized) is 0.35 kJ mol⁻¹ higher than the energy calculated for pure γ main disorder component (as in Table 2). Occupancy ratio is 85:15, this would correspond to flipping four molecules out of 24. Considering this occupancy ratio, and with the assumption that the flipped molecules do not interact, we may estimate the electronic energy for the disordered structure to be 4 × 0.35 kJ mol⁻¹ higher than for major γ component. It means that the disordered structure is energetically less stable by 1.4 kJ mol⁻¹ than the non-disordered γ structure (major component only). When a 1.4 kJ mol⁻¹ value is added to the energy obtained for the non-disordered γ structure (from Table 2, using B3LYPD3 and fixed cell at 10 K, the γ form is −0.9 kJ mol⁻¹ more stable than δ) we see that the γ form is becoming less stable than δ by 0.5 kJ mol⁻¹ at 0 K.

3.4. Entropy, zero-point energy and contribution to enthalpy from lattice vibrations

The entropy and the contribution to enthalpy from lattice vibrations were calculated from frequencies obtained after NoMoRe refinement. Those contributions are temperature dependent and together with ZPE are presented in Fig. 7. As the vibrational contributions to the free energy are positive, a lower value indicates that the structure is more stabilized by the lattice vibrations. From Fig. 7 we can immediately observe that with the increase in temperature two forms, α and γ, are starting to have significantly lower energies, stabilized by entropy. At room temperature the energy difference between polymorphic forms is almost 4 kJ mol⁻¹ (between δ and α or between γ and β). Such energy differences can easily overcome differences in electronic/lattice energies between polymorphic forms.

Figure 7 Contributions to the free energy from vibrations (Hvib +ZPE-TS) for four polymorphic forms as a function of temperature.

In principle, these vibrational contributions can be calculated directly from frequencies obtained from periodic DFT calculations at the Γ point (this is our starting point for NoMoRe). Even with such simple model it appears that the α form is stabilized by entropy, but within this model γ does not exhibit higher vibrational entropy than β (see supporting information). There might be a few explanations for that, and the most obvious one is that with this model we do not consider the change of frequencies due to phonon dispersion. Consequently, we do not consider acoustic modes and some low-frequency modes, which are heavily affected by phonon dispersion and thus might be inaccurately modeled.

Apart from the entropic contributions from vibrations, the configurational entropy, which arises from static disorder, contributes to the γ form free energy. This contribution equals 3.5 J mol⁻¹ K⁻¹, which at room temperature will lower the free energy by 1.1 kJ mol⁻¹, and at 392 K – the temperature of the experimentally estimated phase transition from the α to γ form – around 1.6 kJ mol⁻¹.

3.5. G-T diagrams

Based on the crystal energies and the vibrational contributions to entropy and enthalpy derived from the normal-mode refinements, and by considering the consequences of disorder in the γ form for both enthalpy and entropy, it is possible to calculate the free energies as a function of temperature for all four polymorphs (see Fig. 8). As evident from our calculated energies, it is not straightforward to assess the order of stability at 0 K for the pyrazinamide polymorphs. We therefore make three different curves with different offsets on the abscissa, corresponding to different estimates of the 0 K enthalpies. In terms of the vibrational contribution to the entropy, these models are identical. The three models are presented in the three columns of Fig. 8. Model 1: periodic DFT (B3LYP, fixed cell, TZP, D3) calculations including destabilization of the γ form due to disorder. Model 2: periodic DFT results from Wahlberg et al. (2014) (Approach III, model B3LYP-D/VTZ-mod in that work). Model 3: average values of experimentally observed enthalpy differences, as observed from DSC measurements (Cherukuvada et al., 2010). In this model, we assume that the observed enthalpy differences are temperature independent. For this reason, the vibrational enthalpy calculated from the lattice dynamical model was not included.

Figure 8 The variation of free energies as a function of temperature. The three models are described in the text. The upper part of the figure shows the total G–T curves, whereas the lower part shows the differences in free energies with respect to the δ form. The δ form therefore becomes a horizontal line at G = 0. For the γdis model we are including the entropy arising from disorder in the free energy calculation for γ.

Comparison of Gibbs free energies obtained from the different models reveals the importance of accurate total electronic and lattice energy calculations (Fig. 8). Due to those differences, we do observe that free energies obtained from the two theoretical models differ, especially at low temperatures.

3.6. Discussion

The vibrational contributions to the free energy, as derived from the NoMoRe procedure, shows that the γ and α forms behave similarly, and are stabilized at higher temperatures as compared to the β and δ forms (see Fig. 7).

Whereas the vibrational stabilization of α and γ are similar in size, the disorder in the γ form contributes in two ways to form an enantiotropic relationship between these two polymorphs: first, the disorder decreases the packing energy, i.e. the γ form is enthalpically destabilized by the disorder. At the same time, the disorder adds a residual entropy component to the γ crystal. At higher temperatures, this entropic stabilization effects that the γ form becomes the stable form. Experimentally, this change in stability is observed at 392 K.

Our 10 K structures confirm the disorder found in the γ form at higher temperatures and at the same time rule out any major disorder in any other forms. These accurate structures, being close to the `0 K' ansatz used in most ab initio calculations, provide a good benchmark for further optimization of theoretical calculations of polymorphism in organic crystal systems.

Our difficulties in assessing the order of stability of the polymorphs at 0 K imply that many different G–T diagrams can be constructed, giving very different phase transition temperatures, none of which are in full agreement with the experimentally observed. Since the experimental phase transition temperatures may at the same time be influenced by kinetic factors they may be overestimated. The observed phase transition from δ to α is at 298 K, whereas all our models predict a phase transition well below room temperature. Similarly, our models predict the phase transitions of β to γ to be below room temperature. In contrast, the α to γ transition is predicted to be well beyond room temperature, as observed experimentally.

The effect of thermal expansion and anharmonicity is not part of the NoMoRe approach used in this study. One approach to include anharmonicity would be to impose a quasi-harmonic approach, where a range of NoMoRe models are refined against X-ray diffraction data obtained at differing temperatures. For each temperature, an ansatz could be obtained from periodic DFT calculations performed using the unit-cell dimensions obtained experimentally at that temperature.

Although this approach is not unfolded in the present work, we have performed periodic DFT calculations based on the room-temperature structures obtained from the literature. The calculations of frequencies were performed at the γ point of the Brillouin zone – thus, no contribution from acoustic phonons were included. The thermodynamic properties obtained from these purely in-silico models are compared to similar calculations using the 122 K unit cells in Table S2 of the supporting information. As expected, due to thermal expansion, we observe on average a decrease in the vibrational frequencies at room temperature. This leads to an increased stabilization of all polymorphs. Furthermore, we observe that the delta form is slightly more stabilized compared to the other forms. Thus, including anharmonicity into the models might allow the delta form to be the most stable polymorph in a larger temperature window than we obtain in the G–T diagrams in Fig. 8.