1.1. An open question with regard to mixed-tacticity polyhydroxybutyrates

Polyhydroxybutyrates (PHBs) are thermoplastic polymers that are synthesized by various microorganisms for energy storage (Lundgren et al., 1965). They are renewable by biosynthesis, biodegradable and thermally processable, a combination that makes them of technological interest. In nature, exclusively isotactic PHB is produced from R-3-hydroxybutanoic acid and crystallizes in the α-PHB structure (Okamura & Marchessault, 1967; Barham et al., 1984; Wang & Tashiro, 2016). On the basis of earlier work (Bloembergen et al., 1989; Abe et al., 1994; Kemnitzer et al., 1995), we recently prepared synthetic variants in which defined amounts of S monomers were included randomly into the polymer chains (Haslböck et al., 2018). By nuclear magnetic resonance spectroscopy, we determined the respective compositions' fractions of meso diads f_meso to be quadratically correlated to the fractions of R monomers f_R. Since the f_meso values can be accurately determined in the final material, we used them for quality control and as the characterizing numbers for the different compositions.

An application-oriented aim of the overall venture was to determine the progressions of structural, mechanical and thermal characteristics with f_meso. Hence, in two prior studies, we determined the progression of the fraction of crystalline phase and the accompanying crystallite sizes with f_meso (Haslböck et al., 2018) and some mechanical and thermal properties of the compositions (Haslböck et al., 2019). The latter included glass transition temperatures, which remained constant at 278 K, and melting points, which decreased linearly from 440 K at f_meso = 1.00 to 330 K at f_meso = 0.59, below which no melting signals were detected.

Furthermore, we attempted to find a characteristic that would account for observed anomalies in the progressions of various properties, at least qualitatively (Haslböck et al., 2019). We used a random-number generator to simulate R and S monomer chain makeups and then fitted the iso- and atactic chain segment lengths with exponential decay functions. From the decay coefficients λ for the iso- and atactic components, we calculated the number . This is a qualitative indicator of chain disturbance due to mismatching tacticities and peaks at the intersect of the two λs, which is at f_meso = 0.7 for randomly added monomers. It is there that instances of unexpected mechanical and thermal behaviour were detected (Haslböck et al., 2019).

But there was an issue to be resolved: We reported on fractions of crystalline phase f_c that decreased with decreasing f_meso, but remained above 0.6 down to f_meso = 0.64. Then, we scaled a diffractogram recorded from a rapidly regenerated thin sheet of PHB to obtain the amorphous phase intensities [Fig. 1 of Haslböck et al. (2018)]. The same approach, using ice-water-quenched PHB to record an amorphous phase diffractogram, was used by Bergmann & Owen (2003). Comparing the obtained values with an infrared spectroscopy-based index I_c yielded a reasonably linear correlation [Fig. 10 of Haslböck et al. (2018)]. We were further able to trace the melting enthalpies ΔH_m of our materials by the Gibbs–Thompson relation, suggesting the correctness of the f_c values [Fig. 11 of Haslböck et al. (2019)]. However, the development of f_c to lower f_meso remained unclear, in particular to f_meso = 0.54, of which we had obtained an X-ray diffractogram [Fig. 6 of Haslböck et al. (2018)]. Extrapolating the fitted curve of f_c (f_meso) to f_meso = 0.54 would give a value of f_c = 0.57 ± 0.16, whereas the diffractogram did not show any appreciable Bragg reflections. Similarly, by extrapolating the progression of ΔH_m, one would expect a value of ∼10 J g⁻¹ at f_meso = 0.54, whereas no melting signal was observed. We felt that this issue of `abruptly missing crystalline phase' might be resolved by taking into account the material fraction exhibiting paracrystalline order.

1.2. Paracrystallinity in polymers

Materials whose X-ray diffractograms can be accounted for as originating from structures exhibiting disturbed crystalline and fluid statistical order, or, conversely, disorder of the second kind (the first kind being thermal disorder) are termed paracrystalline, a concept coined by Rinne (1931, 1932, 1933) and expanded by Hosemann (Hosemann, 1950; Hosemann & Wilke, 1968). Rinne pointed out the origin of the term (Lehmann, 1918) and sharpened the nomenclature, distinguishing paracrystals from liquid crystals (the former being solids), and other proposed names such as mesomorphous or pseudocrystals (Rinne, 1933). However, terms such as `mesomorphous smectic' or `with smectic character' remained in use, alluding to structuring also found in liquid crystals (Natta & Corradini, 1960). To not count as amorphous, paracrystals must possess lattice characteristics, such as a fixed number of structural neighbours. However, in contrast to undisturbed crystals (to which we apply the adjective `bulk', for better differentiation and to stress their long-range order in all directions), paracrystals may incorporate structural disturbances that are not systematically transferred to their neighbours, resulting in the loss of long-range order (De Rosa & Auriemma, 2013).

Early on, it was recognized that polymers are likely to exhibit paracrystallinity (Hosemann, 1950). Along their chains, atomic positions are defined by the repeating unit periodicity, while perpendicularly there may be freedom of movement (Natta & Corradini, 1960). Combined with the diverse possibilities of intra- and intermolecular interactions, paracrystallinity may present itself in a large variety of structural arrangements (Hosemann, 1963, 1970). Miller described this structural organization in polymers, which he termed `non-crystalline', as `neither amorphous nor crystalline and […] very stable, for only slight changes in the X-ray scattering curve were detected even after the sample had been stored at room temperature for one and a half years' (Miller, 1960).

A prominent case of paracrystallinity can be found in polymers that exhibit folding, such as polyethylene and PHB (Hosemann, 1963, 1970; Hosemann & Wilke, 1968). Here, `[t]he paracrystalline concept takes into account that each `crystalline' lamella consists of a series of microparacrystallites with grain boundaries in between them' (Hosemann, 1975). Hosemann also included molecular aggregate superstructures (Hosemann, 1950) into the definition (sand patterns on beaches, as well; Hosemann, 1963), although here, the length scale of the paracrystalline order exceeds that accessible to X-ray diffraction.

Paracrystalline regions may be considered structural features – defects – of crystalline arrangements. However, as also outlined above, regions that exhibit paracrystalline order are interdispersed with undisturbed crystalline regions, as are regions showing amorphous order. Furthermore, they exhibit distinct properties. To trace these, they are sensibly treated as separate, intermediate phases (Wada et al., 1967; De Rosa & Auriemma, 2013). There are two general methods to investigate paracrystalline order: directionally and qualitatively by resolving Bragg peak broadening contributions, and quantitatively by allocating intensities of diffractograms.

1.3. Qualification of paracrystalline order from Bragg peak broadening

A directional assessment of paracrystalline order considers Bragg peak broadening. The contributions to the directional integral peak width β due to average crystallite size , microstrain-derived lattice parameter distribution ϕ⁻¹(ε) and a measure of paracrystalline order g can be distinguished by their progressions with scattering vector s = n/d for the lattice plane distances d and the reflection scattering orders n (Hosemann & Wilke, 1968):

Prior to the widespread availability of the Rietveld refinement method (Rietveld, 1969), Williamson–Hall plots (Williamson & Hall, 1953) were used to separate the broadening contributions due to crystallite size and strain. Similarly, linear fits to directional plots of peak width over squared scattering order allowed one to calculate g by equation (2):

Here, ϕ⁻¹(0) is the breadth of the microstrain distribution function, equal to half the apparent strain ε = Δd/d (Stokes & Wilson, 1944). is a measure of the amount of lattice distortion relative to the distortion-averaged lattice plane distances , ranging from 0 for perfect crystals to 1 for ideal gases (Hosemann & Hindeleh, 1995). If expressed directionally in terms of the Miller indices {hkl}, g provides a measure of paracrystalline order between lattice planes for a given direction.

1.4. Quantification of phase contents by allocating X-ray diffractometry intensities

Since the aforementioned broadening is accompanied by a loss of Bragg peak intensity (Hosemann, 1950; Ruland, 1961) one can designate a portion of the scattered, but not Bragg-diffracted, intensity as stemming from paracrystalline domains. The remainder of the coherent background is due to the amorphous phase and thermal diffusive scattering. Depending on the measurement setup, incoherent scattering may also be detected, requiring intensity corrections (Ruland, 1961). In agreement, Mu (1998) demonstrated that scattering from paracrystals attenuates quickly into a continuous background, the intensity of which progresses by a function similar to that for disorder of the second kind cited by Vonk (1973).

An example with direct relevance for the present work was given by Hosemann, separating the previously assigned (Hermans & Weidinger, 1948) amorphous portion of scattering from cellulose materials into amorphous and paracrystalline fractions [Fig. 4 of Hosemann (1950)]. In individual polymer materials, the fraction exhibiting paracrystalline order can be significant; for example, quantification of polytetrafluoroethylene via dilatometry yielded a value of the paracrystalline phase content X_p = 0.48, exceeding that of the bulk crystalline phase, X_c = 0.45 (Ohzawa & Wada, 1964).

In Ruland's (1961) words, the intensities of the `crystalline peaks' and the `amorphous background' cannot be unambiguously correlated with the weight fractions of crystalline and amorphous material, since `even an entirely crystalline substance shows diffuse coherent scattering and a loss in intensity of the diffraction peaks due to thermal vibrations of the atoms as well as to lattice imperfections, effects which have been emphasized in a recent paper by Hosemann et al. (1960) (sic)' [referencing Bonart et al. (1960)]. Therefore, `some structural details are needed to evaluate the crystallinity, or more correctly, the amount of material which shows two- or one-dimensional order […]' (Ruland, 1961). On this basis, and in homopolymers, the determination of bulk crystalline phase fractions by X-ray diffractogram integration over the volume of reciprocal space is performed by equation (3) (Ruland, 1961):

Here, is the scattering vector as a function of the scattering angle θ and the wavelength λ, and I and I_c are the total scattered intensity and the portion thereof within the diffraction peaks, respectively. K is a correction function, wrapping the disorder function D. s₀ and s_p are the integration boundaries and is the squared number-weighted sum scattering factor of all atoms within the unit cell. D can be first-approximated by the thermal Debye–Waller factor (Ruland, 1961; Vonk, 1973).

In the original method, as expanded by Vonk (1973), the intensities within the Bragg peaks, separated by a simulated continuous background, were considered. Then, for materials containing large degrees of structural disorder, the cumulative integral fractions as functions of s_p follow curves, rather than straight lines, when applying the Debye–Waller factor. In this case, equation (3) can (is intended to) account for paracrystallinity, by modifying D (Ruland, 1964). However, this leads to the follow-up issue of selecting suitable disorder functions, accounting for thermal motions, microstrain and paracrystallinity, not only for specific crystal structures (Kavesh & Schultz, 1969) but also for individual crystallographic directions (Ruland, 1961). Worded one way or another, researchers have found the separation of contributions to be the major obstacle in applying equation (3) (Kavesh & Schultz, 1969; Mo & Zhang, 1995; Vonk, 1973).

Subsequent to Ruland's formulation, Rietveld developed his full-profile refinement method (Rietveld, 1969). Given the right structural model and suite of parameters, including the crystallite sizes and thermal and/or structural disorder, Rietveld refinement will result in values of the scattered intensities within the Bragg peaks, which thitherto were determined graphically (Kavesh & Schultz, 1969; Mo & Zhang, 1995; Vonk, 1973). Then, considering the intensities transferred to the continuous background by disorder allows for a separation from the remaining background (Riello, 2004, Section 7.3 in the cited book chapter). Using refined values of I_c and adding the portion of the background due to the accompanying disorder removes the necessity to account for disorder separately via K. Then, equation (3) converges on the value of f_c with increasing s_p – in principle.

In practice, however, Rietveld refinement requires good models for all phases in order to provide robust results, including the background function: `If the polynomial happens to describe the background well, then, as might be expected, [refining the background] works well […]' (McCusker et al., 1999), noting the caveat `happens to'. Riello concluded the same, namely that one should apply a diffractogram from a pure amorphous material, multiplied by a scale factor (Riello, 2004). Alternatively, if the smooth background belonging to the crystalline phases is properly taken into account, `the amorphous contribution can be fairly well described by using a polynomial or other more suited functions' (Riello, 2004), noting the qualifier `fairly'.

So, conceptually, Rietveld refinement works `downwards' from the crystalline structure and the Bragg peaks, whereas separation via Ruland and Vonk's method works `upwards', from the continuous background. These two approaches were distinguished by Riello (2004) in a review of methods. He further pointed out the method of calculating calibration lines from reference samples with known amounts of amorphous phase, as well as our earlier (Haslböck et al., 2018) approach (`limiting the analysis to the 2θ range which corresponds to the first halo of the amorphous pattern') (Riello, 2004).

1.5. Simultaneous considerations

It was the main aim of this work to determine and verify the lattice orientations and amounts of paracrystalline order in mixed-tacticity polyhydroxybutyrates with changing f_meso, by applying the aforementioned qualitative and quantitative approaches simultaneously. This required a Rietveld routine able to identify paracrystalline order among other contributions to peak broadening, as well as knowledge of the scattering profiles from the amorphous and paracrystalline fractions.

We determined a method for distinguishing microstrain and paracrystalline order in a Rietveld refinement. To refined patterns, we applied equation (3), using the convergences of cumulative integrals with increasing s_p on their final values as a means to attribute attenuated Bragg peak intensities. In this equation, we substituted the index f_c for f_i, for any i of the amorphous (am), bulk (bc) and paracrystalline (pc) phases.

The secondary aim was to correlate obtained structural information to previously determined structural (Haslböck et al., 2018), mechanical and thermal (Haslböck et al., 2019) properties.

2.1. Polymer synthesis

Details of the polymer synthesis were reported earlier (Haslböck et al., 2018). In brief, R- and S-β-butyrolactone monomers were polymerized with defined fractions of R, f_R > 0.5. We utilized ethylzinc β-diketiminate as catalyst and 4-methoxybenzyl alcohol as co-catalyst in dry toluene under stirring for 24 h at 353 K, using standard Schlenk techniques. The reactions were quenched with small amounts of methanol, ground with a mortar and washed with methanol. All materials were used as synthesized and after ageing for at least seven days.

From nuclear magnetic resonance spectroscopy, we determined the fraction of meso diads f_meso for each prepared material. Since they are fixed properties of the PHB chains themselves, they were subsequently used as their descriptor. Owing to the spacing between the assessed f_meso, characteristic values or ranges are naturally approximates with an uncertainty given by the distance between adjacent data points. Hence, any statement `f<sub>meso</sub> (<, =, >) x' means `', with the aforementioned uncertainty.

2.2. X-ray diffractometry

The data used in this work were obtained from a powder diffractometer (Miniflex, Rigaku, Tokyo, Japan) with a copper anode and a silicon strip detector (D/teX Ultra, Rigaku) and have been reported on elsewhere (Haslböck et al., 2018). The setup in detail: goniometer radius 150 mm; both Soller slits 2.5°; divergence slit fixed at 0.625°, but closing variably below 10° 2θ; anti-scatter slit 8 mm; no monochromator; Kβ filter 0.06 mm nickel foil; effective receiving slit of the multiline detector 0.1 mm. Two additional measurements were made from samples with f_meso = 0.54 and f_meso = 0.6. In total, 86 measurements were performed, spread over the range of f_meso in groups of two to ten samples per reported data point. The data were evaluated by Rietveld refinement (BGMN, using the Profex interface) (Bergmann et al., 1998; Bergmann & Taut, 2005; Doebelin & Kleeberg, 2015) considering the machine line function, as verified by refining NIST standards 640e and 660c (silicon and lanthanum hexaboride for peak shapes and positions; machine parameter file and refinement results available from the authors). The scattering angle range 5 < 2θ < 75° was considered and the sample offset from the goniometer axis refined. Reflections from the holders, occurring in the ranges 36.2 < 2θ < 37.2°, 42.4 < 2θ < 43.4° and 62.9 < 2θ < 63.9°, were excluded.

We based the bulk and paracrystalline phases on the α-PHB structure with orthorhombic space group 19 and lattice parameters a = 0.573 nm, b = 1.315 nm and c = 0.593 nm (Wang & Tashiro, 2016). Being in the orthorhombic crystal system, and only considering directions normal to the unit-cell sides, we freely equate the normals of the lattice plane families {100}, {010} and {001} with the directions of the lattice parameters a, b and c, for simplicity. Since we are considering statistical averages, the actual lattice parameter dimensions are denoted , and .

The diffractogram from a sample with the lowest f_meso, presented in Fig. 1(a), was taken as the scattering profile of the amorphous fraction, noting its agreement with one measured by Bergmann & Owen (2003). It was used as the background pattern for all refinements, while allowing BGMN a free choice of polynomial and two squared-Lorentzian peaks for required additional (Miller, 1960) background intensities. The paracrystalline fraction was composed of all of the aforementioned intensities, exceeding those of the amorphous pattern.

For the bulk crystalline fraction, the average crystallite dimensions were refined anisotropically, without preferred orientation. To account for the intensity loss from Bragg reflections towards larger s, an isotropic thermal displacement factor B = 8π²〈u²〉 was applied, resulting in values of the Debye–Waller factor (Debye, 1913). The attenuated intensities I_th from the bulk and paracrystalline fractions f_bc and f_pc were tracked during refinement:

Their attribution was important to completing the paracrystalline phase scattering profiles. A portion of the intensity attenuated from the Bragg reflections is due to thermal disorder and another due to structural disorder. We determined these portions by using their attribution to minimize the gradients of the cumulative integrated ratios f_i(s_p). This is similar to Ruland's (1961) original approach, in which the thermal factors themselves were altered to obtain constant values of the crystalline fraction when integrating over different ranges of s_p.

Separating the different peak broadening contributions outlined in equation (1) is complicated by the fact that those of microstrain and paracrystallinity both increase with scattering order n, and therefore with scattering vector s = n/d. In polymers with weakly defined reflections at larger s, a clear differentiation between linear increases due to microstrain and quadratic increases due to paracystallinity (Hosemann & Wilke, 1968) poses a challenge. While refining both influences separately and simultaneously, we found that the starting conditions influenced the results. Reducing both into one number with a variable exponent solved this issue. Hence, we modified equation (1) to equation (5), with parameters v and p, and n = (h² + k² + l²)^1/2:

We define v as the disorder magnitude and p as the disorder indicator, i.e. whether it directly represents microstrain broadening ϕ⁻¹(0) or paracrystalline order g, or portions of both. All of the above were applied according to the {hkl} direction. The corresponding BGMN structure file code section and details about the line shapes are given in the supplementary information.

From the refinement results, we calculated the individual phase fractions via equation (3), with K = 1, s₀ = 0.57 nm⁻¹ and s_p = 7.91 nm⁻¹. On the basis of the work of Sao et al. (1997), we could then attribute a portion of the factor B to displacement due to paracrystalline lattice distortions via equation (6):

For all evaluations, care was taken to carry over the uncertainties from refinement, as well as to consider the variations between samples of the same f_meso. All averaged values are medians. The corresponding uncertainties are the medians of the refinement uncertainties, to which were added the median absolute deviations of the values of individual measurements for each f_meso. Errors of f_meso, i.e. along the abscissa, result from NMR analyses of multiple synthesis batches with uniform initially weighted ratios of R and S enantiomers (Haslböck et al., 2018).

3.1. Polymer synthesis

All materials were obtained as white powders, except the compositions f_meso ≤ 0.6, which were clear and resin like (certainly stationary during measurements).

3.2. X-ray diffractometry

Exemplary intensities from the three refined phases are shown in Fig. 1. Owing to the manner of evaluation, the progressions of the paracrystalline curves do not represent the entire scattering from the paracrystalline phase, but a convolution of scattering due to smectic arrangements and intensities attenuated from the Bragg peaks into the continuous background. The entire paracrystalline scattering includes broadening contributions to the Bragg peaks [examples given in Fig. 1of Mu (1998)]. Increasing intensities and noise at low s are due to the Miniflex's variable receiving slit intensity correction. Since they occur below the range of the observed Bragg peaks, they are safe to ignore.

Figure 1 Recorded diffractograms (black solid curves), as deconvolved into amorphous background (grey solid curves), scattering from bulk crystals (dashed curves) and paracrystalline scattering (dotted curves) of samples with (a) fmeso = 0.54, (b) fmeso = 0.64 and (c) fmeso = 1.00, together with the refinement residuals (thin curves at negative values). In (a), scattering from non-amorphous phases is 0.

Cumulative integration of the respective I_i via equation (3) led to curves of calculated phase fractions f_i as functions of s_p (Fig. 2). Since scattering from paracrystals transitions into a continuous curve more rapidly than that from bulk crystals (Mu, 1998), and Bragg peaks are effectively gone above s = 6 nm⁻¹, the presented paracrystalline progressions approach the true fraction of the paracrystalline phase. Hence, all f_i converge on their final values, which were attained at s_p = 4 nm⁻¹, corresponding to 36° 2θ. The initial f_pc in Fig. 2(b) is a consequence of the aforementioned intensity correction.

Figure 2 Cumulative integrated ratios for the total non-amorphous (black solid curves), amorphous (grey solid curves), bulk crystalline (dashed curves) and paracrystalline (dotted curves) intensities of samples with (a) fmeso = 0.64 and (b) fmeso = 1.00. For fmeso = 0.54, the amorphous ratio is 1.

The bulk and paracrystalline phase fractions over f_meso showed steady progressions: the former increasing logarithmically with f_meso, the latter decreasing linearly (Fig. 3). For comparison, we plotted the fitting curve to the crystalline fractions determined in earlier work (Haslböck et al., 2018) for the range of f_meso from which it was originally derived.

Figure 3 Crystalline phase fractions determined for mixed-tacticity polyhydroxy­butyrate: total non-amorphous (squares and solid lines), bulk crystalline (circles and dashed lines) and paracrystalline (upward triangles and dotted lines). The fit to previously reported values of crystallinity is given by the bold dotted curve (Haslböck et al., 2018). The green solid and red dashed curves denote previously determined progressions of the exponential decay coefficients of the iso- and atactic polymer sequence length histograms, inverted, scaled and shifted simultaneously (Haslböck et al., 2019).

In Fig. 3, we also plotted two curves based on those from an earlier article for correlation purposes [green solid and red dashed lines in Fig. 14 of Haslböck et al. (2019), inverted, scaled and shifted along the abscissa]. The original curves represent the progressions of the exponential decay coefficients λ that describe the length histograms N(n) = of purely isotactic and atactic polymer sequences. Here, N(n) is the number of respective sequences of length n, and n₀ := 1 is the maximum length. The progressions of the individual λs could be recreated by equation (7), using the Lambert W function, the product logarithm:

The function x(f_R, f_S) recreates an empirical relation with the fractions of R and S monomers for each f_meso (Haslböck et al., 2018). For the atactic segments x = (f_R + 0.5)(f_S + 0.5) and for the isotactic segments x = f_R + 0.5f_Rf_S were found to provide suitable progressions of λ with f_meso (Haslböck et al., 2019). The curves shown in Fig. 3 were obtained for n = 0.5, inversion and by shifting the resulting curves by f_meso = 0.1 to higher values.

The thermal factors B decrease with f_meso (Fig. 4). Since the samples with f_meso ≤ 0.6 contained no bulk crystalline portion, no thermal factors were determined and they were omitted from all further presented results.

Figure 4 Plot of the displacement factors for the non-amorphous fractions: total (squares and solid lines), thermal (circles and dashed lines) and paracrystalline (triangles and dotted lines). The previously reported values of E for the entire material are given by the dotted curve (Haslböck et al., 2019).

As also reported earlier (Haslböck et al., 2018), the lattice parameters and remained roughly the same, whereas increased slightly with decreasing f_meso [Fig. 5(a)]. Correspondingly, the densities of the crystalline phase follow a trend towards slightly lower values with increasing tactic disturbance, noting the large error on the density at f_meso = 0.64 [Fig. 5(b)].

Figure 5 Plots of (a) the average lattice parameters (red circles and dashed lines), (green upward triangles and dotted lines) and (blue downward triangles and dash–dotted lines), and (b) the density of the bulk crystalline phase.

Fig. 6 shows the values of the parameters v and p for the directions a, b and c. The former is a measure of the magnitude of disturbance, while the latter indicates whether it signifies microstrain (Δd/d, for p = 1) or paracrystalline structural [, for p = 2] disorder.

Figure 6 Plots of the determined disorder (a) magnitude and (b) indicator, for the directions of a (red circles and dashed lines), b (green upward triangles and dotted lines) and c (blue downward triangles and dash–dotted lines). The black line in (a) marks the progression of the total paracrystalline order magnitude vpc.

The paracrystalline content could be traced by calculating a single p-weighted paracrystalline order magnitude v_pc [equation (8) and Fig. 6(a)] and then matching it to the values of f_pc via equation (9) (Fig. 7):

Figure 7 Plot of the correlations between the paracrystalline content (black upward triangles and dotted lines) and vpc via equation (9) (full black lines with shaded uncertainties).

v_pc⁰: = v_pc (f_meso = 0.64) is the data point to which we pegged the correlation. It is therefore `initio-quantitative': starting from x (v⁰), for the initial magnitude and scaling, it provides quantitative correspondence. While a theory for quantitative correlation is currently lacking, we determined that for all measurements f_pc/v_pc = 6.4 ± 1.2.

4.1. Interpretation of directional disorder, considering the α-PHB structure

In the classic crystal model, c is the direction longitudinal along the polymer chains (Marchessault & Kawada, 2004; Birley et al., 1995). As a consequence, we determined small crystallite sizes for all f_meso in earlier work (Haslböck et al., 2018). In the aforementioned model, a and b are the directions perpendicular to the chain orientations. Out of the two, a is the direction along which single polymer chains are folded (Marchessault & Kawada, 2004; Birley et al., 1995). The folded laths, already extending to their fullest in a and c, are subsequently stacked in direction b, forming lamellae (Marchessault & Kawada, 2004; Birley et al., 1995). The stacking aspect is also supported by our own crystallite size data, which indicate that only the change to a significant degree with f_meso (Haslböck et al., 2018). The lamella lengths in a are achieved by an assembly of laths `out of register' towards one another. The lath edge joints interrupt the crystalline order, and hence can be expected to be independent of lamella length and uniform sizes were determined previously (Haslböck et al., 2018).

In a and c, the crystallites are constituted of single polymer chains. Increasing tactic disturbance leads to unit-cell expansion in c, but not in a [Fig. 5(a)]. Since an observed increase of averaged lattice parameters can be caused by microstrain according to ε = 2ϕ⁻¹(0) (Stokes & Wilson, 1944), it is peculiar that, while increases, v_c decreases (Fig. 6). If the observed expansion is not due to localized microstrain, which leads to a lattice parameter distribution ϕ⁻¹(ε), then it must occur homogeneously throughout the material. Thus, the phenomenon can be traced to the structural changes when exchanging R monomers for their S enantiomers. This requires exchanging the C4 methyl group with the lone C1-bonded hydrogen (Fig. 8).

Figure 8 Unit cell of α-PHB viewed in lattice direction a with two exemplary exchanges of groups to obtain the S enantiomer, marked with red arrows.

The exchange occurs roughly within a plane in the direction of a, along vectors ∼[011]. Since it brings the C4 methyl group into close proximity to the in-chain O1 atom, the helices along c are likely to be forced into a shallower angle, expanding the repeating units in this direction. In a, bonding between the single-chain folds is mainly due to the C4H₃⋯O2 interaction (Wang & Tashiro, 2016). Shifting the C4 methyl group onto the other side of the chain either does not greatly alter their distance or causes the O2 atom, which projects in direction a, to form hydrogen bonds with other adjacent H atoms. Both would explain the weak effect of tactic disturbance on .

In b, however, cohesion is mainly due to Van der Waals forces, requiring a close conformational match easily disturbed by tactic mismatch. It is therefore conclusive that – as indicated by p_b [Fig. 6(b)] – paracrystalline order manifests itself first in b, the most readily dissolved crystal direction, along which different polymer chains are joined together (Marchessault & Kawada, 2004; Birley et al., 1995). Correspondingly, a typical incarnation of paracrystallinity in linear polymers is the formation of smectic structures that resemble lamellar bundles along directions perpendicular to the molecular axes (Natta & Corradini, 1960; Hosemann, 1970). This is in agreement with Hosemann's concept of the nature of paracrystalline order, namely that former net planes are not only unevenly spaced but also distorted: bent, warped, twisted etc., readily envisionable among laths consisting of single polymer chains (Hosemann, 1950, 1970). Nevertheless, with increasing tactic disturbance, p_a increases, indicating that structural disorder of the second kind gradually manifests itself also in a [Fig. 6(b)]. At low f_meso, where the ordered portions of the structure unravel completely, structural disorder manifests itself in c as well, leading to an increased p_c and, more importantly, a sudden increase in v_c (Fig. 6).

4.2. Correlation with prior electron microscopy investigations

In earlier work, we observed branched or linear strands with diameters of 15 nm in low-voltage transmission electron micrographs of PHB with f_meso = 0.54, deposited from chloroform solution [Fig. 8 of Haslböck et al. (2018)]. These showed dark spots at regular intervals of 39 nm. It is our interpretation that these are of the same origin as the granular patterns observed in polyethylene crystals [Fig. 6(b) of Holland (1964)]. Hosemann determined that these `gabardine' patterns in polyethylene, with a repeating length of 30 nm, originate from mismatch between paracrystal blocks within the image plane [Fig. 9 of Hosemann (1970)]. Since changing orientations of entire blocks would not lead to the formation of the then-observed Moiré patterns, he deduced that the orientational mismatch is due to polymer chain kinks within what appear as single crystals. These differ between blocks and therefore interrupt the lattice continuity, but conserve their lattice orientation. From crystallite size considerations, he then determined that the pattern repeating length corresponds to dimensions perpendicular to the chain orientations [Fig. 10 of Hosemann (1970)].

In our case, we note that the observed regular intervals between dark spots correspond to the crystallite dimensions L _b found in undisturbed PHB, at large f_meso (Haslböck et al., 2018). Furthermore, we had earlier found that `[t]he development of the crystallite dimensions of the iso-PHB unit cell extrapolates […] to L_a = 15.3 nm and […] to L_b = 14.5 nm for f_meso = 0.5' (Haslböck et al., 2018), which corresponds to the observed strand diameters. A likely explanation is that the strands observed with the electron microscope consist of sequences of disordered paracrystal blocks with dimensions similar to those of ordered bulk crystallites.

While PHB at f_meso = 0.54 exhibited no crystalline order, either via X-ray diffraction (Haslböck et al., 2018) or in thermal analyses (Haslböck et al., 2019), it also did not show signs of paracrystalline ordering when measured in bulk, for this work. However, in our prior work, we presented a measurement from a thin film of f_meso = 0.54, which showed the characteristic scattering profile determined for smectic structural arrangements herein [dotted line in Fig. 1(b) and thin lines in Fig. 1 of Haslböck et al. (2018)]. Evidently, in thin films regenerated from solution, paracrystalline arrangements are formed more readily than in the bulk material. Since the transmission electron microscopy samples were also regenerated from solution, the likely explanation from the prior paragraph is indeed likely. The meaning of this finding for the bulk material is that the diminishing crystallite dimensions L_b with decreasing f_meso determined earlier (Haslböck et al., 2018) may be interpreted as the primary building blocks retaining their dimensions, but being gradually transformed from bulk to paracrystalline order.

4.3. Development of fractional composition with f_meso

The values of total non-amorphous phase are within the measure of uncertainty of the values we previously reported as the fractions of the crystalline phase (Haslböck et al., 2018). It is convenient that we earlier selected an integration cutoff at 35° 2θ (Haslböck et al., 2018) (then based on the first halo of the amorphous pattern), since it marks the approximate point of convergence via equation (3).

Fig. 3 shows that the break in f_c and ΔH_m at f_meso ≃ 0.6, questioned in the Introduction, exists. And, when equating f_c with the total non-amorphous phase content, it is rather sharp. However, the underlying bulk crystalline contents transition gradually to 0 along a curvature that is well described by the plotted Lambert W function, while the paracrystalline contents steadily increase going to f_meso = 0.6. This matches the gradual transformation of the building blocks from bulk to paracrystallinity, as proposed at the end of the previous section. Since the paracrystalline phase already incorporates directional fluid statistical order (Hosemann, 1950; Hosemann & Wilke, 1968), the transition to the amorphous phase with complete fluid-like order at f_meso = 0.6 can occur more readily than directly from the bulk crystalline phase.

As described in the Results, the red and green curves in Fig. 3 are not equal to those presented earlier (Haslböck et al., 2019). However, their qualitative progressions are good matches for the observed f_bc and f_pc. At 0.64 < f_meso < 0.7, both their contents approach equal proportions, below which they are replaced by the amorphous phase. f_meso = 0.71 ± 0.05 is the value where the materials were earlier shown to exhibit maximum energies of fracture (Haslböck et al., 2019). These were caused by major changes to the materials' strengths and fracture strains, which exhibit a `sweet spot' at 0.64 < f_meso < 0.7. However, the numbers of f_bc and f_pc themselves do not change suddenly; their quantities merely intersect. We therefore suspect that there is a feature of the spatial distributions of the bulk and paracrystalline phases yet unaccounted for. On the basis of the current findings, and considering the spacing of the reported data points around f_meso = 0.71 ± 0.05 (Haslböck et al., 2019), we propose that in future work the mechanical properties be further refined in the range 0.64 < f_meso < 0.7.

4.4. Thermal factors and mechanical properties

The paracrystalline portion of the total displacement factor expectedly increases with f_pc (Fig. 4). Their absolute values and their relation to the total B are supported by their similarity to the values of the `Ruland Parameter (k) and First [thermal] and Second [paracrystalline] Kinds of Distortions (k′ and k₂) in Ramie' cellulose, as determined by Sao et al. (1997). They determined near-constant values of k′ from untreated, heat-treated or alkali-treated mercerized cellulose (Sao et al., 1997). By contrast, in this work, the thermal portion of the total displacement factor changes markedly with f_meso, following the latter's progression.

The thermal B is a measure of the average displacement of chain elements due to thermal motions, counteracted by their elastic bond suspension. In general, thermal factors decrease with increasing elastic parameters (Debye, 1913), allowing one to determine elastic constants e (Sasaki et al., 2013). In earlier work, we were able to trace Young's moduli E, as determined by tensile testing, with a two-phase model using the total amorphous and crystalline contents (Haslböck et al., 2019). We note that the progression of B corresponds qualitatively and inversely to the E determined for the crystalline phases, which decreased to lower f_meso. Remarkably, when considering the measured E for the entire material (Haslböck et al., 2019), details that were not considered in the two-phase model can be found in the progression of B: the curvature at 0.75 < f_meso < 0.9 and the deviations from the respective prior trends at f_meso = 1 [Fig. 4 and supplementary Fig. S3(b)].

This finding, then, supports the idea that tactic disturbance `loosens up' the crystal structure, leading to the reduction of the average binding strengths. This, in turn, is supported by the corresponding crystalline phase densities [Fig. 5(b)] and further by our qualitative observation that the solubility of mixed-tacticity PHB in chloroform increases with decreasing f_meso.

4.5. Fitting approach

Only by including the two additional broad peaks adjacent to the main amorphous phase peak in the refinement were we able to obtain overall plausible and consistent results. This scattering [dotted line in Fig. 1(b)], described in the literature as stemming from smectic arrangements, strongly resembles amorphous phase scattering, as also observed in paracrystalline (or `mesomorphous smectic') arrangements of polypropylene (Natta & Corradini, 1960; Zannetti et al., 1969). A portion thereof was also present in a pattern which we earlier presented as the amorphous phase pattern (Haslböck et al., 2018). Owing to their similar progressions, the same results were obtained for the respective `crystalline' phases earlier (Haslböck et al., 2018) and `total non-amorphous' phases now, as traced in Fig. 3.

As pointed out in the Results, a portion of the intensity in the Bragg peaks stems from the paracrystalline phase, leading to their quadratic broadening with s and allowing us to determine g via equations (1) or (5) (Mu, 1998). While the intensities attenuated from the paracrystalline phase follow a nominally different function (Vonk, 1973; Mu, 1998), the progressions of D for disorder of the first and second kinds are similar; examples are shown in supplementary Fig. S1. Hence, they are virtually indistinguishable from the thermal background [Fig. 4 of Hosemann (1950)].

We found that accounting for attenuation via one factor D, then attributing the attenuated intensities, was necessary in order to not `lead the algorithm'. Accounting for mixed thermal and structural attenuation directionally would – in Kavesh and Schultz's words, and recalling that K wraps D [equation (3)] – necessitate the `preparation of a K chart for an anisotropic disorder function of two or more unequal nonzero components', which `would be awkward' (Kavesh & Schultz, 1970).

The measures of fitting quality were varied, typically with 5 < χ² = (R_wp/R_exp)² < 20 (Toby, 2006). Notably, χ² increased with sample crystallinity and therefore fittable signal. This is expected by its manner of calculation and illustrates the limited absolute informative value of R factors (Toby, 2006). We therefore further determined that we had achieved the best sensible fit by following Toby's conclusion that `the most important way to determine the quality of a Rietveld fit is by viewing the observed and calculated patterns graphically and to ensure that the model is chemically plausible' (Toby, 2006). For comparison, we ran the refinements accounting only for micro-strain, i.e. omitting the program lines for paracrystalline disorder shown in the supplementary information. Then, the average χ² for all refinements increased from 7.9 ± 1.2 to 8.2 ± 1.2. This illustrates the improvement of fitting quality by accounting for disorder of the second kind: minor, but evidently sufficient to yield clear results (Fig. 6).

We also compared our fitting results with prior Rietveld refinements performed on PHB. Bruckner et al. (1988) refined three proposed models of the α-PHB structure to recorded data, arriving at a fitting quality number for the best matching structure of . I_o is the observed, I_c the calculated and I_bg the total background intensity, for which we summed all non-bulk crystalline contributions. In the present refinements, this figure was R_all = 0.092 ± 0.004 for all assessed materials, and R_iso = 0.119 ± 0.004 for the samples composed of purely isotactic PHB.

An interesting comparison was provided by Calos & Kennard (1994), who performed refinements on freshly cast and degraded films of iso-PHB (i.e. with f_meso = 1) with a `goodness of fit', which we assume is χ<sup>2</sup>, of 23.5. They, too, detected large microstrain along the c axis, and that `[t]he pattern displays [strain and thickness broadening] effects as the (020), (110) and (040) peaks stand out very sharply, whereas the general trend of all other peaks is to broaden at a greater rate as 2θ increases.' Close inspection of their pattern `b' of a degraded PHB film shows that the {020} and {040} reflections at 13.4 and 27.0° 2θ are present, the former being sharper than the latter. However, the {060} reflection at 41.0° 2θ is barely visible. It is our interpretation that this is the result of the quadratic increase of reflection broadening associated with paracrystalline order in direction b.

While we finally settled on the method of accounting for all intensities during a Rietveld refinement, we found Vonk's method suitable to recreate the finally determined f_bc and B from the raw Bragg peak intensities (without thermal diffusive scattering) (supplementary Figs. S2 and S3) (Vonk, 1973). Since Vonk's method includes correcting for Compton scattering, we were able to determine that the quantity of detected incoherently scattered X-rays was indeterminably small, as expected from an energy-resolving silicon strip detector.