3.1. Aspherical-atom refinements

Two types of aspherical-atom refinements were performed: in invariom refinement (Dittrich et al., 2005, 2006, 2013) the molecular electron-density distribution is reconstructed from Hansen/Coppens' multipole-model parameter values (Hansen & Coppens, 1978) as tabulated in the generalized invariom database (Dittrich et al., 2013). In Hirshfeld-atom refinement (HAR) (Jayatilaka & Dittrich, 2008) the electron density of the asymmetric unit is obtained by a single-point energy calculation.

Invariom refinements. For structure models based on invariom refinements a least-squares refinement of positions and displacement parameters was carried out using the program XDLSM of the XD2006 package (Volkov et al., 2006). The program INVARIOMTOOL (Hübschle et al., 2007) was used to set up XD system files for that purpose. Refinement was against F² with a SHELXL-type weighting scheme, and the R₁ factor was calculated for all reflections with . Crystallographic details are given in Table 1.

Table 1 Crystal data of N-acetyl-L-4-hydroxyproline monohydrate from invariom refinements GoF = goodness of fit; GoFW = goodness of fit (weighted). Crystal data                 Chemical formula C7H10NO4·H2O Formula weight 191.18 Cell setting, space group Orthorhombic, P212121 Temperature (K) 9 30 50 75 100 150 200 250 a (Å) 9.854 (3) 9.853 (4) 9.866 (7) 9.884 (6) 9.9026 (2) 9.9408 (2) 9.9748 (2) 10.0123 (2) b (Å) 9.249 (3) 9.251 (5) 9.250 (7) 9.253 (6) 9.2485 (2) 9.2479 (2) 9.2492 (2) 9.2556 (2) c (Å) 10.144 (2) 10.145 (2) 10.149 (6) 10.155 (3) 10.1662 (2) 10.1875 (2) 10.2103 (2) 10.2441 (2) V (Å3) 924.5 (4) 924.7 (7) 926.2 (11) 928.7 (9) 931.06 (3) 936.55 (3) 941.99 (3) 949.32 (3) Z, F(000) 4, 408 Dx (Mg m−3) 1.374 1.373 1.371 1.367 1.364 1.356 1.348 1.338 Radiation type Synchrotron Synchrotron Synchrotron Synchrotron Mo Kα Mo Kα Mo Kα Mo Kα μ (mm−1) 0.070 0.061 0.061 0.061 0.116 0.116 0.115 0.114 Crystal form, colour Rectangular, colourless Rectangular, colourless Crystal size (mm) 0.34 × 0.28× 0.28 0.54 × 0.27 × 0.14                   Data collection                 Diffractometer Huber Type 512 Oxford Diffraction Xcalibur S Data-collection method φ scans ω and φ scans Absorption correction None Analytical Tmin, Tmax n/a n/a n/a n/a 0.959/0.986 0.954/0.987 0.960/0.989 0.956/0.989 No. of measured reflections 45747 25178 44258 45127 39746 30837 30309 17876 No. of independent reflections 8304 7775 7803 7809 10866 7826 7829 4420 No. of observed reflections 7885 7262 7372 7255 7744 5673 4860 3245 Criterion for observed reflections Rint (%) 0.040 0.038 0.055 0.051 0.037 0.039 0.039 0.020 (°), 31.90, 1.022 31.88, 1.000 31.90, 1.000 31.87, 1.000 53.28, 1.132 53.32, 1.000 53.31, 1.069 36.25, 0.833                   Invariom refinement                 Refinement on F2 R1 0.026 0.028 0.026 0.028 0.031 0.029 0.029 0.025 No. of reflections 7885 7262 7372 7255 7744 5673 4860 3245 No. of parameters 131               H-atom treatment Invarioms: calculated H position, bond-length elongated, Uiso refined; HAR: all parameters adjusted Weighting scheme                 1/ + [] (P = + ) [0.06P2+ 0.04P] [0.04P2+ 0.05P] [0.04P2+ 0.04P] [0.05P2+ 0.02P] [0.04P2+ 0.07P] [0.05P2+ 0.05P] [0.06P2+ 0.04P] [0.04P2+ 0.08P] GoF 1.76 1.44 1.48 2.02 2.81 2.96 2.12 3.84 GoFW 0.96 0.95 0.94 1.00 0.81 0.84 0.82 0.81 , (e Å−3) 0.36/−0.25 0.32/−0.22 0.27/−0.21 0.30/−0.25 0.36/−0.21 0.25/−0.16 0.20/−0.17 0.16/−0.12

CCDC 990102–990109 contain the supplementary crystallographic data for the X-ray structures. CIF files including intensities are only provided for the invariom refinements, since the same intensities were also used for HAR.

Scattering factors, their local atomic site symmetry and invariom names as well as the model compounds these were derived from are given in Table 2. H-atom positions were initially calculated with SHELXL. In invariom refinement the X—H bond distances were then elongated during initial scale-factor refinement to optimized bond distances of the respective model compound for the invariom assigned to the H atom. This new H-atom position was then constrained to have the same shift as the parent X atom. Only U_iso values were freely refined. This procedure was followed because it is also feasible when conventional data of lower resolution than the data studied here are available. Moreover, idealized H-atom positions provided better input for the MO/MO cluster computations (see §3.3), since idealized positions facilitate reaching convergence. Ratios of hydrogen U_iso to U_eq of the parent atom were then averaged for H atoms sharing the same invariom name using the program APD-TOOLKIT.⁴ For direct comparison with HAR, free refinement of H atoms was also performed and the results obtained (not shown) are very similar.

Hirshfeld-atom refinement. In Hirshfeld refinement the electron density from single-point energy calculations is used and partitioned into atomic contributions using Hirshfeld's fuzzy boundary partitioning scheme (Hirshfeld, 1977). Fourier transform (Jayatilaka, 1994) then gives aspherical atomic scattering factors. Atomic positions and ADPs are adjusted to best fit the experimental data using these scattering factors. In an improved implementation of HAR in the quantum crystallography program TONTO (Jayatilaka & Grimwood, 2003), cycles of molecular electron-density calculations, aspherical-atom partitioning and least-squares refinement are now iterated to convergence in an automatic manner (Capelli et al., 2014). The Hartree–Fock method was used in combination with the basis set cc-pVTZ (Dunning, 1989). A supermolecule cluster approach was chosen to calculate a wavefunction for both molecules of the asymmetric unit for use in HAR (Woinska et al., 2014). The structural model used in HAR included individual positional parameters and isotropic ADPs for H atoms. Ratios of hydrogen U_iso and U_eq of the parent atom were again averaged for H atoms sharing the same invariom name. As expected and shown before for three urea derivatives (Checińska et al., 2013), both types of aspherical-atom models, the Hansen & Coppens multipole model and HAR, give similar figures of merit and anisotropic ADPs of the non-H atoms with experimental X-ray data.

3.2. Neutron diffraction

As mentioned before, the H-U_eq/X-U_eq ratios from neutron diffraction provide benchmark values for this study. One of the advantages of neutron diffraction is that the scattering lengths of the elements that correspond to atomic scattering factors in X-ray diffraction are constant. Stewart (1976) demonstrated that U_iso and U_eq from single-crystal X-ray and neutron diffraction differ, and that U_eq will be in between the arithmetic and geometric mean of the diagonal elements of the mean-square displacement matrix. Since we are interested in the ratio of hydrogen U_iso and U_eq of the parent atom, conventional least-squares adjustment can nevertheless provide relative reliable experimental estimates of atomic motion at a particular temperature. Equivalent isotropic displacements H-U_eq⁵ (orthorhombic system) were obtained both by geometric and by arithmetric averaging the diagonal elements of the matrix of the anisotropic displacements of H atoms (Fischer & Tillmanns, 1988), and both give the same ratios within the estimated uncertainty. In contrast to the deposited structural model, refinements were evaluated without using split-atom sites to model rotational disorder in the methyl group above 150 K. Structural models are given in the supporting information.⁶

3.3. Theoretical computations

A quantum mechanical cluster computation was performed to complement the experimental results. The computation was initiated using the experimental geometry from invariom refinement at the lowest temperature of 9 K with idealized hydrogen positions and elongated X—H distances. The method/basis set for optimizing these model compounds was B3LYP/D95++(3df,3pd). The utility program BAERLAUCH (Dittrich et al., 2012) was used to generate a cluster of 17 asymmetric units packed around a central unit. The water solvent molecule was optimized together with the main molecule. Preliminary QM/MM calculations [HF/6-31G(d,p):UFF] ensured that this cluster size leads to convergence and is suitable to reproduce experimental ADPs at low temperature. Calculations to obtain final results employed the MO/MO basis-set combination B3LYP/cc-pVTZ:B3LYP/3-21G. Only the central molecule was optimized, whereas the surrounding 16 asymmetric units were kept at fixed positions. Normal modes were calculated and transformed to Cartesian atomic displacements after optimization.

On the basis of the discussion by Dunitz et al. (1988), the temperature dependence of atomic motion can be described in analogy to a Boltzmann-type distribution of the harmonic oscillator. Atomic motion at higher temperatures can therefore be estimated by the formula given by Blessing (1995):

Although the molecular Einstein approach underlying the MO/MO calculations is not able to take into account lattice vibrations with acceptable accuracy, such a cluster calculation can provide a H/parent-atom U_iso/U_eq ratio, which is however dominated by internal atomic motion. Estimates so derived predict a higher ratio than the experimentally observed ratios from neutron and X-ray diffraction and require a U_eq scale factor. To reach agreement between theory and experiment, and to take the temperature dependence into account, it was therefore necessary to go back to the TLS+ONIOM approach (Whitten & Spackman, 2006) and to include the experimental TLS contribution, treating the whole asymmetric unit as a rigid body. In this process the internal atomic relative displacement predicted by the MO/MO computation was subtracted from the experimental ADP data at a given temperature prior to the TLS fit (Schomaker & Trueblood, 1968). Both TLS fit and subtraction were performed by the program APD-TOOLKIT. A more sophisticated (and computationally more demanding) theoretical method based on periodic computations of different-sized unit-cell assemblies was studied by Madsen et al. (2013); for reproducing temperature dependence the TLS+ONIOM approach was sufficient.

4.1. Temperature dependence of U_iso/U_eq of riding hydrogen and parent atom from X-ray data

Prior to further analysis, a way to distinguish H atoms and their chemical environment is required. One choice would be the well established SHELXL AFIX groups. However, this would not distinguish H atoms exhibiting a distinct vibrational behaviour in theoretical calculations, e.g. an OH group in ethyl alcohol and one in phenol. The invariom formalism (Dittrich et al., 2013) allows a finer distinction. Here H atoms that share the same invariom name are in the same covalent bonding environment and have the same number of next-nearest non-H neighbours, so it was used for classification throughout.⁷ Vibrational modes of individual invarioms (as derived from their model compounds) in other molecules will be investigated in a forthcoming study.

We can now consider the ratio of hydrogen U_iso and parent-atom U_eq from X-ray diffraction at different temperatures. Initial observations with invariom refinements on D,L-serine (Dittrich et al., 2005) indicated a temperature dependence at very low temperatures. Subsequent tests using the IAM showed that the IAM does not provide the model precision required to obtain significant results (Thorn, 2012). Our first question was therefore whether the U_iso/U_eq ratios from aspherical-atom refinements on NAC·H₂O are able to reproduce the temperature dependence seen for D,L-serine. Fig. 3 shows such ratios for several hydrogen invarioms. Values were either obtained from invariom refinements with constrained riding hydrogen positions, but adjusted hydrogen U_iso (Fig. 3a), or by free least-squares refinement of positional and isotropic displacement parameters with HAR (Jayatilaka & Dittrich, 2008) (Fig. 3b). As one can see, the programs/methods used, XD (Fig. 3a) (Volkov et al., 2006) and TONTO (Jayatilaka & Grimwood, 2003) (Fig. 3b), give comparable results. Both refinements do indeed show the expected temperature dependence and even distinguish different hydrogen invarioms from X-ray data, although the standard deviation associated with each value is non-negligible (not shown for clarity).⁸ At very low temperatures the relative motion of H atoms relative to their parent atoms is clearly appreciably extended compared to higher temperatures.

Figure 3 Temperature dependence of the Uiso/Ueq ratio from the X-ray data of N-acetyl-L-hydroxyproline monohydrate. (a) Invariom refinement with constrained hydrogen positions and refined Uiso. (b) Hirshfeld-atom refinement with freely refined hydrogen positions/Uiso, both using the same X-ray diffraction data.

This temperature dependence can be understood by looking at the low- and high-temperature limits of equation (1) as well as the transition temperature between both limits. Such dependence can be understood by considering the evolution of ADPs of atoms of different mass with temperature (Bürgi & Capelli, 2000). Division of the mass- and temperature-dependent functions and with masses yields a function with the observed shape. Vibrations of atoms with larger contributions from higher internal frequencies are more prominent at lower temperatures, while at higher temperatures the atomic mass independent external modes dominate the overall amplitudes.

Interestingly, the data set that was an outlier in the expansion of the unit-cell volume at 67–75 K shows further deviations in atomic displacements: hydrogen invarioms of the type H1c[1c1h1h] mainly show a deviating behaviour with respect to the other atoms at higher temperatures. This is due to rotational disorder of the methyl group, and it is easily conceivable that the differences in the lattice constants seen at 67–75 K are due to the rotation becoming more frequent, either starting from this temperature or due to temperature fluctuations at this data point. We have previously studied similar disorder in methylaminobutyric acid hydrochloride by difference electron-density plots and molecular-dynamics simulations (Dittrich et al., 2009). The abnormal temperature dependence of the three H1c[1c1h1h] methyl-hydrogen invarioms is proof that rotational disorder is also present in the acetyl group of NAC·H₂O. We will study rotational disorder in this molecule and its anhydrous form in more detail in a subsequent study.

Since positional and displacement parameters are correlated, limiting model flexibility (constrained hydrogen positions) seems to make the onset of additional rotational motion more apparent in invariom refinement, whereas free refinement of positions and U_iso seems to lead to an over-parameterized model in HAR.

4.2. QM/MM and MO/MO calculations

We were interested in reproducing the temperature dependence of U_iso by using the TLS+ONIOM approach (Whitten & Spackman, 2006). For this purpose the above-mentioned two-layer ONIOM computation using the coordinates from the 9 K X-ray diffraction experiment was combined with a TLS fit at each temperature to provide another set of results that includes information independent from experiment.

Details of the procedure need to be highlighted prior to a discussion of the results. Before performing the TLS fit the computed internal modes were subtracted from the experimental non-H-atom ADPs. Contrary to expectation, this is not accompanied by an improvement of the TLS R factors (not shown) with temperature, since the internal ADPs of heavy atoms are mostly spherical in shape and get almost completely absorbed in the TLS ADPs. Nevertheless, such a correction is physically reasonable and we recommend that it is performed. Furthermore, the agreement of the ratio of U_iso/U_eq seen in the aspherical-atom refinements of the X-ray data improves when this internal TLS contribution is taken into account.

Another detail concerns the low-frequency modes describing the movement of the asymmetric unit in the crystal framework. Low-frequency modes have a very large impact on the overall displacements, which can be derived directly from equation (1). Since the approximations present in the theoretical method do not allow the estimation of these frequencies with sufficient accuracy, low-frequency modes were omitted in the calculation of ADPs. A frequency threshold of 200 cm⁻¹ was found to be adequate (Madsen et al., 2013). The required information on the overall displacement is instead taken from the TLS fit, which yields more reliable values. The TLS+ONIOM approach is hence an attractive computational method to understand the ratio of H-U_iso/parent U_eq when experimental TLS contributions are available. It reproduces the temperature dependence nicely, although rotational disorder cannot be predicted. More work is required for ab initio prediction of the temperature dependence by theoretical computations without any experimental input. So far it can only provide an independent source of information for the internal modes and requires the application of the TLS fit; theoretical methods are nevertheless best suited to provide H-U_iso/X-U_eq ratios since experimental errors are limited to ADPs used in the TLS fit.

We now compare these TLS+ONIOM results to those from neutron diffraction, our experimental benchmark (Fig. 4). Since neutron diffraction data sets were not collected at temperatures of 30, 50, 75 and 100 K, these data points are absent in the comparison with high-resolution X-ray and TLS+ONIOM results. The TLS+ONIOM approach confirms that individual displacements of hydrogen invarioms are distinguishable mainly at temperatures below 100 K. Rotational disorder cannot be predicted from this approach, whereas it is also detectable in the neutron data at higher temperatures. Good agreement of neutron diffraction and the TLS+ONIOM approach is found for the temperature-dependent ratio of hydrogen U_iso or U_eq and the parent atom, which also agrees rather well with the X-ray results in Fig. 3. However, at higher temperatures HAR and neutron diffraction show a trend that deviates from the other methods, with the ratio being higher than 1.5, whereas the ratio is smaller in invariom refinement. This is probably due to the predicted/constrained hydrogen positions in invariom refinement, which impose a beneficial limit on the flexibility of the structural model here. Since the rigid-body fit in the TLS+ONIOM approach is based on the invariom results, a similar temperature dependence to that in invariom refinement is observed.

Figure 4 Temperature dependence of the Uiso/Ueq ratios obtained by TLS+ONIOM and neutron diffraction. (a) Internal vibrations from MO/MO ONIOM calculations and TLS fit against ADPs obtained by invariom refinement. (b) Refinement against neutron diffraction data.

A comparison of Figs. 3 and 4 indicates an overall surprisingly good agreement for each curve of H-U_iso/X-U_eq versus temperature over the whole range, especially when taking into account that different methods/experiments were used. All four methods consistently indicate that at very low temperatures the ratio H-U_iso/X-U_eq can be as high as four, e.g. for H atoms attached to an sp³ C atom with three non-H-atom neighbours (corresponding to AFIX 13 in SHELXL). Moreover, all four methods consistently confirm (or reproduce in the case of TLS+ONIOM) the temperature dependence that is predicted from equation (1). Conventional IAM structure determinations employing riding hydrogen constraints – and likewise models with aspherical scattering factors – should therefore take the temperature-dependent ratio into account.