4.1.1. IAM fitting to the data

During the IAM kinematical refinement on the experimental data, no restraints or constraints were needed for the coordinates or ADPs. H atoms were visible on residual electrostatic potential maps (Fig. S1 in the supporting information) and, after refinement, it was clear that the amino acid was in its zwitterionic form. The ADPs of the non-H and H atoms were refined anisotropically and isotropically, respectively. After the IAM refinement, all the ADPs of the non-H atoms were positively definite, as shown in Fig. 2. The R1 and wR2 values were 13.88 and 37.12%, respectively. The residual electrostatic potential max/min values were 0.207/−0.216 Å⁻². The shift towards negative values of the residual potential was also reflected in the residual potential map plotted at the ±0.15 Å⁻² contour [Fig. 3(a)], and confirmed by fractal residual plot [Fig. 3(c), IAM; more details about the meaning of fractal plots are available in the supporting information] to be a global trend for a wide range of values (values larger than ca 0.16 Å⁻² on an absolute scale). The F_obs versus F_calc plot (Fig. S2, IAM) showed only a slight trend towards overestimation of F_calc in relation to F_obs, suggesting that there was little dynamical effect present in the data. All these points further confirm that the L-alanine data set seems to be of relatively good quality compared to typical 3D ED/microED data for organic crystals published so far.

Figure 2 Atomic displacement ellipsoid plot of L-alanine at the 50% probability level after IAM refinement against the experimental data.

Figure 3 Residual electrostatic potential maps of L-alanine after (a) IAM and (b) TAAM refinement against the experimental data at ±0.15 Å−2 contours (green positive and red negative), and (c) fractal dimension plot for the residual potential of the entire unit cell after IAM (blue open circles) and TAAM (red full circles) refinements.

Recently published 3D ED data on L-alanine (Khouchen et al., 2023), collected up to 0.50 Å resolution, showed a completeness of 56%, which is relatively low in comparison to the data presented in this work, and an R_int value of 11.11%. During the IAM kinematical refinement, all non-H atoms were refined with anisotropic ADPs, but the ADPs and coordinate parameters of the H atoms were constrained. The R1 and wR2 values were 14.44 and 35.55%, respectively, with residual potential max/min values of 0.23/−0.18 Å⁻². The published L-alanine data seem to be of not worse quality than ours, apart from the problem with completeness and con­strained H atoms.

4.1.2. IAM versus TAAM fitting

The TAAM kinematical refinement was performed against the L-alanine experimental data starting from the crystal structure model obtained from IAM refinement. The TAAM refinement resulted in im­prove­ments of the refinement statistics (Table 1) and hence the presumably better structure model. The R1 and wR2 values were improved after TAAM refinement as compared to IAM; the values dropped by 0.75 and 0.54%, respectively, indicating a better fit of the model to the experimental data. The residual potential after TAAM refinement was more featureless compared to IAM, as shown in the residual potential maps [Figs. 3(a) and 3(b)]. The visual observation was confirmed by a fractal dimension plot [Fig. 3(c)], where the curve for TAAM is more narrow (less noisy map) and closer to the parabolic shape (more random, less systematically biased map) than for IAM. The effect of the improved fitting was also evident in both the maximum and minimum residual potential values. After TAAM refinement, these values decreased by 0.007 and 0.004 Å⁻² in absolute value, respectively. Overall, the improvement in the fitting addressed specific negative residual potential regions present in the IAM residual potential, which were subsequently removed by TAAM refinement, as evidenced by the left branch of the fractal dimension plot for TAAM being visibly shifted towards zero compared with IAM. The distribution of residual po­tential seen from the experimental data after the IAM refinement resembled, to some extent, the distributions of deformation electrostatic potential (Fig. 4), although it was quite noisy. Deformation electrostatic potential maps should illustrate the changes is electrostatic potential appearing due to formation of the chemical bonds and inter­molecular inter­actions, and are computed as a difference between the crystal electrosatic potential and the electrostatic potential computed from superposition of the electrostatic potential of neutral spherical atoms. The deformation potential maps in this work were computed as the TAAM–IAM Fourier maps, to take into account the influence of resolution and atomic displacement parameters on the map. The TAAM–IAM maps show the effects of the formation of chemical bonds on the electrostatic potential, as modelled by TAAM, but not polarization due to inter­molecular inter­actions.

Figure 4 2D Fourier deformation electrostatic potential map (Å−2) of the L-alanine crystal computed from TAAM–IAM difference on the structure from the experimental TAAM refinement. The 2D map is plotted on the best plane passing through the N1, C2, C1, O1 and O2 atoms of the central mol­ecule.

The F_obs versus F_calc plots were similar for the IAM and TAAM refinements (Fig. S2). F_calc from TAAM tended to be more like F_obs, especially for the most intense reflections. The F_obs versus F_calc plot for TAAM strengthens the suggestion that there were minimal dynamical effects present in the data.

The observations regarding the fitting statistics done for the L-alanine experimental data follow the results from the simulated data. The R1 value dropped by 1.61% after the TAAM refinement against the simulated data as compared to IAM (Table S2). The residual potential after TAAM refinement was visibly more featureless as compared to IAM [Figs. S3(a) and S3(b)], and the max/min residual potential values after TAAM became smaller by 0.005/0.079 Å⁻² and closer to each other on an absolute scale. The fractal dimension plots showed the same trends as for the experimental data [Fig. S3(c)], though the dominance of negative values in the IAM residual potential was much more visible and both fractal dimension curves, for IAM and TAAM, were narrower com­pared to the experimental results, due to lack of noise (random or systematic due to dynamical scattering or other effects) in the simulated data.

4.2.1. IAM fitting to the data

As for L-alanine, no restraints or constraints on the coordinates for all atoms, anisotropic ADPs for non-H atoms or isotropic ADPs for H atoms were necessary during the IAM refinement of the α-glycine structure against the experimental 3D ED data. H atoms were visible on residual electrostatic potential maps (Fig. S4) and, after refinement, it was clear that the amino acid was in its zwitterionic form. After the IAM refinement, the ADPs of the non-H atoms were positively definite, as shown in Fig. 5. The R1 and wR2 values were 15.96 and 35.78%, respectively, slightly greater than for L-alanine (Table 1). The residual po­tential was noisier than for L-alanine [wider fractal curve; Fig. 6(c)] and more visibly dominated by negative values [Figs. 6(a) and 6(c)], from the ±0.15 Å⁻² values and larger on an absolute scale. The max/min residual potential values were 0.366/−0.434 Å⁻². Most of the negative residuals were located close to the non-H atoms or around the covalent bonds, as shown in Fig. 6(a). The F_obs versus F_calc plot (Fig. S5, IAM) showed some trend towards overestimation of F_calc in relation to F_obs, being visibly bigger for strong reflections. For some strong reflections, the F_calc was ca twice as large as F_obs. Compared to L-alanine, the deviation of the plot from the F_obs = F_calc line was much bigger, suggesting there were more dynamical effects present in the data.

Figure 5 Atomic displacement ellipsoid plot of α-glycine at the 50% probability level after IAM refinement against the experimental data.

Figure 6 Residual electrostatic potential maps of α-glycine after (a) IAM and (b) TAAM refinement against the experimental data at ±0.27 Å−2 contours (green positive and red negative), and (c) fractal dimension plot for the residual potential of the entire unit cell after IAM (blue open circles) and TAAM (red full circles) refinements.

The first published 3D ED data for α-glycine (Broadhurst et al., 2020) were collected up to a resolution of 0.70 Å and showed a completeness of 85% after merging data for six crystals, and an R_int value of 31.8%. The crystal structure model was refined with restraints and constraints. The R1 and wR2 values were 21.9 and 51.8%, respectively, which are relatively higher than the statistics for the α-glycine data from this work. The residual potential max/min values were 0.23/−0.25 Å⁻².

In another article (Klar et al., 2023), the 3D ED data had a completeness of 40.0% at a resolution of 0.59 Å. The IAM kinematical refinement was carrried out with five restraints. The R1 and wR2 values were 13.6 and 15.9% respectively. The residual potential max/min values were 0.412/−0.420 Å⁻². The data seem to be of a quality comparable to the data from this work, although with significantly lower completeness. After dynamical refinement, the R1 and wR2 values were 6.8 and 8.8%, respectively, and the residual potential max/min values were 0.197/−0.162 Å⁻². This demonstrated the effectiveness of the dynamical approach in achieving a better fit of the model to the data.

4.2.2. IAM versus TAAM fitting

The TAAM refinement against experimental electron diffraction data for α-glycine improved the fitting of the model to the data. After TAAM refinement, the R1 and wR2 values became smaller by 1.25 and 1.53%, respectively (Table 1). The max/min residual potential values became smaller by 0.044/0.105 Å⁻² on an absolute scale. The residual potential map was much cleaner after TAAM refinement compared to IAM, as shown in Fig. 6(b). The fractal dimension curve for TAAM confirmed that the TAAM refinement led to less noisy residual potential (more narrow curve) and allowed the modelling of some of the unmodelled potential by IAM negative residuals (more symmetric curve), but still the TAAM residual potential showed slightly more negative than positive features [Fig. 6(c)].

In the case of α-glycine, the distribution of the experimental residual potential after IAM refinement [Fig. 6(a)] more closely resembled the deformation potential (Fig. 7) compared to L-alanine. This observation suggests that the data for α-gly­cine contained more chemical information than what IAM can adequately model. The small negative features remaining in the residual potential after TAAM refinement sug­gested that either (i) TAAM alone was insufficient and some effects affecting the electrostatic potential of α-glycine crystal were not accounted for, like polarization due to inter­molecular inter­actions, or (ii) TAAM was appropriate, and other factors beyond modelling the potential played an important role here, such as dynamical scattering.

Figure 7 2D Fourier deformation electrostatic potential map (Å−2) of the α-glycine crystal computed from TAAM–IAM difference on the structure from experimental TAAM refinement. The 2D map is plotted on the best plane passing through the N1, C2, C1, O1 and O2 atoms of the central mol­ecule.

The F_obs versus F_calc plots were similar for the IAM and TAAM refinements (Fig. S5). Again, F_calc from TAAM tended to be closer to F_obs, especially well visible for strong reflections. After TAAM refinement, the tendency to overestimate F_calc in relation to F_obs, traditionally attributed to the presence of dynamical effects, was smaller but still visible.

The behaviour of fitting characteristics when going from the IAM to TAAM refinement of α-glycine against experimental data was confirmed by the simulated data. For the simulated data, R1 dropped by 1.46% after the TAAM refinement as compared to IAM (Table S2). The minimum residual potential peak was lower by 0.066 Å⁻² in absolute value, but the maximum peak was higher by 0.031 Å⁻². Nevertheless, the maximum and minimum peaks from the TAAM refinement became more symmetrically distributed around zero than those from IAM. Furthermore, the residual potential map after TAAM refinement was more featureless as compared to IAM [Figs. S6(a) and S6(b)], though some small non-random features remained after the TAAM refinement. The presence of some systematic effect in the simulated data not accounted for by TAAM was also reflected in the fractal dimension plot, where the curve for TAAM was still not parabolic [Fig. S6(c)]. This suggests that, also in the case of the experimental data, we see the insufficiencies of TAAM.

4.3.1. IAM fitting to the data

The IAM kinematical refinement for urea on the experimental data was run without any restraints or constraints, analogously as for L-alanine and α-glycine. In the case of urea, the H atoms were also visible on residual electrostatic potential maps (Fig. S7). All ADPs were positively definite (Fig. 8). The R1 and wR2 values after IAM were 17.56 and 38.56%, respectively (Table 1), which were slightly worse than for α-glycine and L-alanine. The residual potential was dominated by negative values [Fig. 9(a)]. Negative peaks were located at covalent bonds, mainly around the N atom. The max/min residual potential values were 0.250/−0.333 Å⁻², somewhat similar to α-glycine, but closer to zero. The fractal dimension analysis confirmed that the IAM residual potential was biased mostly toward negative values, the left branch of the curve spanned farther away from the zero line (from the −0.12 Å⁻² value outwards) and departed from the parabolic shape very fast [Fig. 9(c)], and a slight bias on the positive residual potential was also visible.

Figure 8 Atomic displacement ellipsoid plot of urea at the 50% probability level after IAM refinement against the experimental data.

Figure 9 Residual electrostatic potential maps or urea after (a) IAM and (b) TAAM refinement against the experimental data at ±0.23 Å−2 contours (green positive and red negative), and (c) fractal dimension plot for the residual potential of the entire unit cell after IAM (blue open circles) and TAAM (red full circles) refinements.

The F_obs versus F_calc plot for urea was similar to that for α-glycine, the only difference being that the departure of the most intense reflection from the F_obs = F_calc line was not so strong (Fig. S8, IAM).

4.3.2. IAM versus TAAM fitting

After applying the TAAM refinement against the experimental electron diffraction data for urea, there was an improvement in the fitting quality as compared to IAM (Table 1). The R1 and wR2 values became better by 1.28 and 1.47%, respectively. The negative values of the residual potential were much closer to zero [Figs. 9(b) and 9(c)], though some small bias toward negative values remained after TAAM refinement. The max/min residual potential values moved toward zero by 0.011/0.018 Å⁻² after TAAM refinement compared to IAM.

The experimental IAM residual electrostatic potential for urea [Fig. 9(a)] closely resembled the computed deformation electrostatic potential (Fig. 10). Both potentials exhibited strong negative peaks at the N1—C1 and N1—H1 bond regions, as well as positive peaks between the two symmetry-related H2 atoms. The deformation potential map for urea effectively illustrated the compensation of negative potential resulting from the lone electron pairs at the O1 atom by positive potential generated by the H2 and H1 atoms. Consequently, there were fewer strongly negative residual potential peaks in the vicinity of the O atom in the urea crystal compared to the O atoms in L-alanine and α-glycine; the latter were involved in fewer hydrogen bonds. Another reason could be that the O atom in urea was slightly less negatively charged than the O atoms in alanine and glycine according to the TAAM modelling based on the MATTS pseudoatom data bank.

Figure 10 2D Fourier deformation electrostatic potential map (Å−2) of the urea crystal computed from TAAM–IAM difference on the structure from experimental TAAM refinement. The 2D map is plotted on the plane passing through all the atoms of the central mol­ecule.

The F_obs versus F_calc plots were similar after the IAM and TAAM refinements (Fig. S8), but the TAAM results were usually closer to the F_obs = F_calc line, analogously as for L-ala­nine and α-glycine.

Comparing the experimental refinements with the simulated data for urea, it could be concluded that the trends in improving fitting quality while going from IAM to TAAM refinements were very similar. In simulation, the R1 value dropped by 1.58% after the TAAM refinement compared to IAM (Table S2). The residual potential was less negative and more featureless when comparing the TAAM to the IAM refinement (Fig. S9). The min/max residual potential values were smaller by 0.013/0.079 Å⁻² in absolute value. Inter­estingly, after simulated TAAM refinement, the residual potential showed some systematic features not accounted for by TAAM. It was most probably electrostatic potential (electron density) polarization due to neighbouring mol­ecules not modelled by the TAAM parametrized with the MATTS data bank. The experimental data were, obviously, burdened with noise (possibly both random and systematic), as indicated by the significantly wider fractal curves after experimental refinements compared to the very narrow curves observed for the simulated data.

4.4.1. The non-H-atom bond lengths

In the case of the bond lengths between the non-H atoms [Figs. S10(a)–(c)], the IAM and TAAM refinements on the experimental data for L-alanine, α-glycine and urea led to the values being almost the same, both from a chemical and a statistical point of view. The root-mean-square difference (RMSD) between the experimental results from the IAM and TAAM refinements was only 0.003 Å (Table 2), which was much smaller than the averaged value of the standard uncertainties (s.u. values) resulting from the least-squares minimiza­tion, the later being equal to 0.017 Å (Table S3). Similar trends were observed for the IAM and TAAM refinements on the simulated data, which showed a very small RMSD of 0.0009 Å, being almost statistically insignificant when compared to the average s.u. values of 0.0005 Å. For both the experimental and the simulated data refinements, the non-H-atom bond lengths were close to the theoretical values resulting from periodic DFT geometry optimization (target values for refinements on the simulated data), with RMSDs of 0.022 and ca 0.002 Å for the experimental and simulated data, respectively (Table 2). Only in the case of the simulated data could the differences be considered statistically significant (i.e. were more than three times larger than the s.u. values); however, they were negligible from a chemical point of view (the lengths deviated from the target values differed by only 0.04 to 0.03%).

The experimentally derived non-H-atom bond lengths from this work were similar to the experimental lengths observed in high-resolution X-ray structures (Escudero-Adán et al., 2014; Aree et al., 2012; Jha et al., 2020), and the experimental IAM refinements showed an RMSD of 0.015 Å.

Compared to the published 3D ED data, the L-alanine non-H-atom bond lengths in Khouchen et al. (2023) were 1% longer than in the experimental IAM refinement from this work, but 0.8% shorter than the theoretical DFT values. The non-H-atom bond lengths for the first published α-glycine data (Broadhurst et al., 2020) were bigger by 2.5 and 1.8% when compared to the experimental IAM refinement and the theoretical DFT values from this work, respectively. Accordingly, the non-H-atom bond lengths from other published work on α-glycine (Klar et al., 2023) (kinematical refinement) were bigger by 0.2% compared to the experimental IAM re­finement and smaller by 0.7% when compared to the theoretical DFT values from this work. After dynamical re­fine­ment, the values were bigger by 0.1% and smaller by 0.8%. Apparently, dynamical refinement has not influenced greatly the positions of the non-H atoms.

4.4.2. The X—H bonds

In case of the X—H bonds, the experimental TAAM refinement usually led to shorter bonds compared to IAM [Figs. S10(d)–(f)], with an RMSD of 0.04 Å (Table 2). The X—H bonds from the experimental TAAM refinements were closer by ca 0.03 Å to the theoretical values from periodic DFT geometry optimization as compared to experimental IAM refinements; the RMSD values were 0.05 and 0.08 Å for TAAM and IAM, respectively (Table 2). When compared to experimental average neutron distances (1.033 Å for N⁺—H, 1.099 Å for Csp³—H, 1.092 Å for Csp³—H₂ and 1.077 Å for Csp³—H₃) (Allen & Bruno, 2010) or to the neutron diffraction structure in the case of urea (Swaminathan et al., 1984), the experimental TAAM refinement values were closer only for L-alanine and urea. For α-glycine, the experimental IAM refinement values were more similar to the average neutron distances. All the above differences observed for the X—H bond lengths were, however, on the border of being statistically significant. They were bigger by only 2–4 times than the experimental s.u. values (Table S3), the latter being on average equal to 0.03 and 0.04 Å for the TAAM and IAM refinements, respectively.

The IAM and TAAM refinements on the simulated data showed similar trends for the X—H bonds as seen from the experimental data. The simulated IAM X—H bonds were usually longer than for TAAM [Figs. S10(d)–(f)], with an RMSD of 0.012 Å (Table 2), and were usually longer than their target theoretical values from periodic DFT geometry optimization, with an RMSD of 0.011 Å. The simulated TAAM X—H bonds differed from their target values by a similar value (the RMSD was 0.013 Å), but sometimes they were too short and sometimes too long. All the differences were on the border of statistical significance, i.e. they were only 2–4 times the s.u. values. The s.u. values were on average equal to 0.004 and 0.003 Å for the simulated IAM and TAAM, respectively.

It is clear, however, that the X—H bond lengths from electron diffraction were significantly more accurate than the experimental X—H bond lengths from IAM refinements against X-ray diffraction data [Figs. S10(d)–(f)] (Escudero-Adán et al., 2014; Aree et al., 2012; Jha et al., 2020), the latter method underestimated their values by ca 0.18 Å (RMSD between the experimental IAM refinements on the 3D ED and on the X-ray diffraction data).

4.4.3. Valence angles for non-H atoms

Valence angles for non-H atoms in all three compounds resulting from experimental IAM and TAAM refinements (Fig. S11) were very similar to each other (differences smaller than the respective s.u. values; Table 2) and chemically satisfactorily similar to refinements on the simulated data and target values from periodic DFT geometry optimization (differences within 4 s.u.; Table S3). The simulated data confirmed that the IAM and TAAM refinements led to very similar accuracy in valence angle determination.

4.4.4. Atomic displacement parameters for non-H atoms

To analyze the atomic displacement parameters, we focused on the U_eq values for the non-H atoms and the U_iso values for the H atoms. The U_eq parameters for the non-H atoms in all three compounds from the experimental IAM refinements were always smaller, by ca 4–8%, compared to TAAM [Figs. S12(a)–(c)], with an RMSD of 0.0009 Å⁻² (Table 3). The differences were, however, statistically insignificant; they were within 1 s.u. (Table S4). Similar trends were also visible in the simulated data, with ca 3–7% differences and an overall RMSD of 0.00056 Å⁻². For the simulated data, the differences were on the border of being statistically significant; they were within 3–4 s.u.

By comparing the results of the refinements on the simulated data to their target values, it could be concluded that IAM refinements usually led to smaller values of U_eq than the expected target values [Figs. S12(a)–(c)], with an RMSD of 0.00029 Å⁻², and TAAM refinements led for some atoms to too large and for others to too small values, with an overall RMSD of 0.00041 Å⁻². All the differences were again statistically on the border of being significant; they were within 3 s.u. The benefits of using TAAM over IAM were almost neglegible for the simulated data from this work; however, they were very visible in the case of the published simulated data for carbamazepine (Gruza et al., 2020), paracetamol and 1-methyl­uracil (Olech, 2022). A more extended analysis of the refinements on the simulated data showed that the behaviour of the refined values of the ADPs are strongly dependent on the resolution of the data. Indeed, for a resolution of d_min = 0.83 Å, i.e. worse than in this work, the IAM refinement could lead to U_eq values for the non-H atoms smaller by 34–74% than their expected target values, whereas the TAAM refinements could lead to values only up to 7% different.

The experimental IAM and TAAM U_eq parameters for the non-H atoms in L-alanine and α-glycine were, on the other hand, significantly larger, by ca 116–124 and 30–40%, respectively, than the experimental reference data from high-resolution X-ray diffraction at 100 K (which were also target values for the simulated data) (Escudero-Adán et al., 2014; Aree et al., 2012). For L-alanine, the RMSDs were 0.0132 and 0.0141 Å⁻² for IAM and TAAM, respectively (Table 3), and they were more than 16 times larger than the average s.u. values (Table S4). For α-glycine, the RMSD values were much smaller (0.0023 and 0.0031 Å⁻² for IAM and TAAM, respectively) and on the border of being statistically significant. A somewhat similar situation was seen for the experimental U_eq values for urea; here the RMSDs had very similar values (0.0023 and 0.0027 Å⁻²) when compared to the reference neutron diffraction data from 123 K (the target values for simulated data) (Swaminathan et al., 1984) and similarly were on the border of being statistically significant, though for urea the trend that all U_eq values were larger than for the reference was not observed.

The huge difference for U_eq for L-alanine is even more strange when we consider the fact that the reference X-ray data were collected at 100 K and the 3D ED experiment in this work was conducted at 81 K; hence, smaller values were expected. Even when compared to the L-alanine structure determined at 150 K by neutron diffraction (Malaspina et al., 2019), the non-H U_eq parameters from this work were still larger. Because TAAM refinement against simulated data led to U_eq parameters differing from their target values by only ca ±3%, some effects other than the scattering model must have led to such large 3D ED experimental ADPs, most probably radiation damage and possibly dynamical scattering.

The non-H U_eq parameters from the published 3D ED data for L-alanine (Khouchen et al., 2023) were also higher (by 23%) than the reference X-ray diffraction data, but 78% lower than the experimental IAM refinement results presented in this work. The U_eq values of the non-H atoms for α-glycine from the first published 3D ED data (Broadhurst et al., 2020) were bigger by ca 50 and 170% when compared to the experimental IAM refinement and reference X-ray diffraction values from this work, respectively. Accordingly, the U_eq values from the second published data (Klar et al., 2023) (kinematical refinement) were bigger by ca 52 and 193% when compared to the experimental IAM refinement and reference values from this work, respectively. After dynamical refinement, the U_eq values became smaller compared to the kinematical ones and were bigger by ca 12 and 55% when compared to the IAM and X-ray reference from this work, respectively. Apparently, the dynamical approach may significantly lower the size of the atomic displacement parameters, but still none of the 3D ED data for L-alanine and α-glycine, from this work or published, reached the values expected for the temperature at which the data were collected.

4.4.5. Atomic displacement parameters for H atoms

In the case of the H atoms, the experimental U_iso parameters from the IAM refinements differed from those of the TAAM refinements by an RMSD of 0.005 Å⁻², which converts to ca 15%, but the difference was either positive or negative [Figs. S12(d)–(f)] and were statistically insignificant due to being smaller than 1 s.u. (Table S4). The IAM U_iso parameters for the H atoms from refinements on the simulated data were always smaller than from TAAM, by an RMSD of 0.0035 Å⁻² (ca 13%), the difference being statistically significant (equal to 7 s.u.). The simulated TAAM values were always closer to their target values than IAM; the RMSD values were 0.0023 and 0.0040 Å⁻², respectively.

Similarly, as for the non-H atoms, the experimental U_iso values for most of the H atoms in L-alanine [Fig. S12(d)] tended to be bigger compared to the reference values estimated by the SHADE method for 100 K, with RMSDs of 0.016 and 0.011 Å⁻² for IAM and TAAM, respectively, though the relative differences (53 and 39%) were not as large as for the non-H atoms. For α-glycine and urea, the U_iso values of the H atoms were sometimes bigger and sometimes smaller compared to the reference values estimated by the SHADE method for 100 K in the case of α-glycine and to the reference neutron diffraction data from 123 K (Swaminathan et al., 1984) in the case of urea [Figs. S12(e) and S12(f)]. For α-glycine, the U_iso values differed by an overall RMSD of 0.003 Å⁻² for both IAM and TAAM, the differences being very small and statisticaly insignificant. For urea, the overall RMSDs were 0.041 and 0.034 Å⁻² for IAM and TAAM, respectively, which were large but still on the border of being statistically significant if individual s.u. values for the two H atoms in urea were taken into account [Fig. S12(f)].