2.1. Background theory

The neutron scattering amplitude of a nucleus can have a number of different values, owing to neutron spin and to isotope effects, so the scattering has to be divided into two parts: coherent and incoherent scattering. The coherent part, depending on the average value of the scattering amplitude, contains all the information about the relative position and motion of the nuclei taken in pairs, while the incoherent scattering depends only on the motions of each atom taken independently. As shown by Van Hove (1954), the resulting cross section can be expressed in terms of the corresponding scattering functions, S_coh(Q, ω) and S_inc(Q, ω) for the coherent and incoherent scattering cases, respectively. These functions, which depend only on the interactions between the nuclei, define the corresponding double differential scattering cross sections (for materials containing only one element) as follows (Squires, 1978):

and

Here, σ_coh and σ_inc represent the two total cross sections, Q is the momentum transfer vector [Q = (4π/λ)sinθ being the magnitude of the vector, where θ is half the scattering angle and λ is the wavelength of the incident neutrons], E′ is the kinetic energy of a given scattered neutron where the incident energy is E, is the average (and is the mean-square average) of the bound scattering length for the nucleus, k and k′ are the incident and final wavenumbers, respectively, of the scattered neutron, and ω is the frequency of an excited phonon. The scattering functions, S_coh(Q, ω) and S_inc(Q, ω), were originally defined as here for a single species of nucleus. However, for a general non-Bravais lattice (with unit cells containing more than one atom), the terms have to be summed over the atoms in the unit cell, although this results in a scattering function which, in the strictest sense, is not S(Q, ω) as originally defined. Hence, the effective one-phonon scattering functions for a system with multiple atomic species, as used here, should be written as S′_coh/inc(Q, ω), where

and

for neutron energy gain [ and 〈n_s〉] and energy loss [ and 〈n_s + 1〉] of a system, generating a phonon of wavevector q. Here n_s is the number of phonons in mode s at thermal equilibrium. In equations (3) and (4), N is the number of atoms in the unit cell in the (non-Bravais) system and the inner summation is over these atoms, d, with mass M_d and a position vector within the unit cell of r_d, while W_d is the associated Debye–Waller factor. The outer summations are over τ, the reciprocal lattice vector, and s, the phonon mode of frequency ω_s, providing a polarization vector e_ds for each normal mode, as obtained by solving the dynamical matrix. The reader should be aware that some texts adopt slightly different definitions of the phase factor of the polarization vector. For example, the text by Turchin (1965) defines the phonon wave at a position r_d within the unit cell to have the phase of the travelling wave at that point, whereas Squires (1978) defines this wave as having a phase relative to that of the travelling wave at the corner of the unit cell. The Turchin version leads to a different general formulation of the coherent inelastic cross section from that given in equation (3). This `frame of reference' difference, whilst being irrelevant for a monatomic lattice, is crucial to the present objective for the case of more than one atom/unit cell. Here the form of the polarization vector used by Turchin will be adopted, as this is the form employed in GULP. Hence the corrected form of equation (3) is

where ξ_ds is the polarization vector on the alternative definition given above.

Once the expressions for the neutron scattering functions have been established, the next step is to introduce the means by which the phonon frequency (square root of the eigenvalue) and the polarization vectors (eigenvectors) are obtained for a given phonon wavevector, q. The approach, briefly summarized here, follows the standard Born–von Karman method (Born & Huang, 1956), where forces are described in terms of potentials between pairs of atoms. This method results in the construction of a dynamical matrix of the form

for each of the pairwise vectors, r, at reciprocal space wavevector, q. The eigenvalues, ω(q), and eigenvectors, ξ, are then obtained from equation (7):

which is solved using (I is the identity matrix) and hence by diagonalizing the resultant matrix. For every q vector there is thus a set of 3d eigenvalues (and therefore frequencies) and for each eigenvalue a corresponding eigenvector (i.e. a set of polarization vectors) for each of the d atoms; this results in the notation ξ_ds and ω_s for eigenvectors and eigenvalues, respectively.

The frequencies and polarization vectors so obtained are then used to calculate the scattering function presented in equation (5). When performing a powder-averaged calculation, it is necessary to sample reciprocal space in a series of concentric shells, each corresponding to a given magnitude of the momentum transfer vector, Q, as it is rotated through θ and φ. For each magnitude and orientation of Q, the program calculates the corresponding values of q by selecting the nearest reciprocal lattice point and taking q relative to this point. From this value of q, the dynamical matrix [equation (6)] is then generated and the corresponding eigenvalues and eigenvectors obtained [see equation (7)]. Fig. 1 illustrates this sampling method, along with a diagrammatic representation of the Q vector relationship with the lattice vector, τ, and phonon wavevector, q.

Figure 1 (a) The principal poly-CINS reciprocal space sampling method used in the Scatter code. (b) Selecting the nearest reciprocal lattice point to Q provides the reciprocal lattice vector, τ, such that q remains within the first Brillouin zone (shaded area).

The resulting data are then output using a histogram-averaging method, where defined intervals are used to create a mesh of data `pixels'; here each pixel corresponds to a set range in the amplitude of Q (referred to as Q, where Q = |Q|) and to a set frequency interval. The intensities obtained for this interval in Q are sorted into the specified histogram in ω. Assembling such slices for each Q yields S(Q, ω). Resolution broadening of the scattering δ functions in Q and ω, Debye–Waller factors may be applied before summation of the intensities, but this is not necessary for present purposes.

2.2. Semi-empirical force constant modelling of aluminium

Aluminium is a very well studied material that has attracted attention of late owing to the interest in the use of light metal hydrides for hydrogen storage (Schuth et al., 2004; Kang et al., 2004). Results from recent work (Budi et al., 2009) on the generation of new semi-empirical force constant models for use in cluster calculations has typically been compared against reliable DFT calculations (Pham et al., 2011) (where comparisons are normally made with zone boundary frequencies), bulk properties (as above), and the density of vibrational states as obtained by both measurement and calculation (Tang et al., 2010). The simplicity of its crystal structure and the proliferation of these fitting models suggest the use of aluminium as an ideal test material for the methodology presented.

When selecting models for aluminium from the large number of possible variants in the literature the emphasis here has been to test the utility of models in frequent use. For convenience, we will start with a simple Lennard-Jones 12–6 potential (Lennard-Jones & Ingham, 1925) fitted to the elastic constants (C11, C22 and C44) of aluminium, following the approach suggested by Halicioǧlu & Pound (1975). Although this type of model is generally considered unsuitable for the study of metallic systems, its very unsuitability (as well as its very low computational cost and the rather general nature of the potential itself) suggested its use as a model for assessing the more heavily parameterized (and considerably more computationally expensive) embedded atom method potentials.

The most successful methodology applied to the semi-empirical modelling of metals, however, is the embedded atom method (EAM) (Daw & Baskes, 1983), originally developed by Daw and Baskes to study hydrogen embrittlement in nickel and now adapted for use in lattice dynamics and cluster calculations. For this reason, it was decided to test the effectiveness of potentials of this type for predicting the dynamical properties of aluminium and to compare the results with the simplest available potential – the Lennard-Jones (LJ) model, described above.

The EAM models most frequently used in studies of pure and alloyed periodic systems are the Sutton–Chen functional EAM potential (Sutton & Chen, 1990), the Cleri–Rosato tight binding EAM potential (Cleri & Rosato, 1993), the Streitz–Mintmire EAM potential (Streitz & Mintmire, 1994), the Mei–Davenport modified EAM (MEAM) potential (Mei & Davenport, 1992) and the parameterized EAM (NP-B; Jasper et al., 2005) potential. Sheng et al. have published results for an optimized EAM potential (Sheng et al., 2011), but as they neglected to include EAM parameters for their model (obtained by fitting to DFT calculations), it has not been practical to include this model in the comparison. Likewise the many-body potential of Mishin et al. (1999), derived from a spline fit to DFT calculations and to bulk data, provided excellent agreement with the measured dispersion curves, but the paper did not include an explicit model parameterization and so this model has also been omitted. Both the Cleri–Rosato and Streitz–Mintmire models were considered for implementation in this study, but as the emphasis here is on the inelastic scattering analysis, these models were neglected for brevity. Hence the three models selected for further analysis are the Sutton–Chen, the Mei–Davenport and the NP-B. Functional forms and explanations of these standard potentials have been omitted from the text, but the expressions and parameters used are given in Table 1.

Table 1 Functional forms and associated parameters of the potential models for aluminium Potential model Form of EAM functional EAM density Pair potential Sutton–Chen , A = 1.000 eV , C = 1303.927 Å6 , A = 592.41956 eV Å6 NP-B , Ec = 2.834 eV, α = 4.954, β = 5.203, γ = 5.824, δ = 8.969, φ0 = 0.2095 eV, s1 = 6.928, s2 = 3.861, s3 = 15.50; ρe cancels with ρe in density term , c0 = 0.4333, c1 = −7.305, c3 = 29.812, c4 = −54.44, c5 = −15.50, r0 = 2.760 Å , φ0 = 0.2095 eV, r0 = 2.760 Å, δ = 8.969, γ = 5.824 Mei–Davenport , Ec = 3.39 eV, α = 4.60, β = 7.10, γ = 7.34759, δ = 7.35, φ0 = 0.1318 eV, s1 = 12.0, s2 = 6.0, s3 = 24.0; ρe cancels with ρe in density term , c0 = 0.64085, c1 = −6.83764, c3 = 26.75616, c4 = −47.16495, c5 = −8.60834, r0 = 2.8638 Å , φ0 = 0.1318 eV, r0 = 2.8638 Å, δ = 7.35, γ = 5.58441; MDF taper r(cut) = 5.382 Å; MDF taper f(cut) = 0.522 Å Lennard-Jones 12–6 potential N/A N/A , A = 38763.011, B = 118.33287

2.3. Dispersion curves from the semi-empirical models

The experimental data presented in this analysis of dispersion curve predictions are taken from the triple-axis neutron spectroscopy study of Stedman & Nilsson (1966), as presented in Fig. 2.

Figure 2 Dispersion curves calculated for the semi-empirical models (with initial parameters) used in this work, compared with experimental triple-axis spectrometer data gathered by Stedman & Nilsson (1966) at 80 K (red points). Heavy black lines represent the LJ 12–6 model, heavy grey lines the Mei–Davenport EAM, heavy yellow lines the NP-B EAM and thin black lines the Sutton–Chen EAM.

As a general preamble, it is worth pointing out the salient features of what is a very well studied system. In the experimental data, the face-centred cubic (f.c.c.) aluminium structure gives rise to the expected form of the dispersion curves in the [100] and [111] directions – doubly degenerate transverse acoustic (TA) modes (as a result of the fourfold and threefold rotational symmetry along these respective axes) and a single longitudinal acoustic (LA) mode. These modes are dominated by the first nearest neighbour interaction (hence the near-sinusoidal form). Thus reasonable agreement for the gradient of the near-linear part of the curve at low |q| (the velocity of sound) and the frequency at which the curves cross the zone boundary is sufficient to match the shape of the curves. The observed flattening of the [111] TA curve near the zone boundary is a consequence of contributions to bonding from electron screening and exchange interactions at the Fermi surface (Hafner & Schmuck, 1974) and, in consequence, cannot be modelled with short-ranged pair potentials. However, the contribution of this feature to the dynamics (and hence to the prediction of bulk properties) is relatively small, and further consideration of this region can be neglected in the present work – especially as it can be modelled with longer-range pair-wise interactions or directly via DFT.

The dispersion curves in the [110] direction, along which there is only twofold rotational symmetry, produce an LA mode and two distinct TA modes. The shapes of the TA modes are determined by the second nearest neighbour contributions (even in models that do not explicitly include this interaction); the maximum for the higher-frequency TA mode (found to be displaced from a symmetry point) is determined by the second nearest neighbour contribution, and its accurate positioning requires a model with considerably more near neighbour interactions (eight to ten interaction shells is typical). In aluminium, this maximum is found close to (0).

Turning to the predicted dispersion curves, the Lennard-Jones 12–6 potential, fitted to the elastic constants, performs better than all of the EAM potentials in comparison with experiment. It should be noted, however, that this model is specifically targeted at describing the curvature of the experimental (single-crystal) dispersion curves but is not fitted to give zero stress at this geometry. As can be seen in Fig. 2, it provides excellent agreement with the LA modes in all crystallographic directions. The lack of nearest neighbour interaction terms beyond the first predictably generates only reasonable agreement with the TA modes in the [100] and [110] directions; this clearly demonstrates the need for additional terms for second and further nearest neighbour interactions, as does the inaccurate |q| positioning of the [110] TA maximum, although the model does predict the maximum frequency of this mode very well.

It should be noted that the dispersion curves obtained from the EAM models, also shown in Fig. 2, were not originally compared with the experimental dispersion curve data as their main use has been for studying clusters and associated energetics. Hence, the accurate prediction of the lattice dynamics was less relevant and poor fits are not unexpected. The Sutton–Chen model provides the worst agreement with the experimental dispersion curves, being significantly different from experiment across the entire range of |q|, for all three high-symmetry directions, and the prediction of the frequencies at the zone boundaries, most notably the gamma point, provides a poor dynamical description of the aluminium lattice.

The NP-B model, which clearly overestimates the stiffness of the bonding between atoms, produces dispersion curves that are an improvement on those of the Sutton–Chen potential, although the overbinding of the potential produces frequencies for all modes that are considerably higher than the experimental values.

The Mei–Davenport model performs best out of the EAM potentials chosen for this comparison. This model provides a near-perfect agreement for the TA mode in the [100] direction, over the entire range of |q|, and gives very reasonable agreement for the LA mode in the same direction, with close agreement in the lower-q region (|q| < 0.5) and reasonable agreement at the zone boundary (within 20%). The [110] and [111] directions give rise to similarly reasonable agreement to that provided by the LA mode in the [100] direction: going from very good agreement at low q (|q| < 0.5) to reasonable agreement at the zone boundary in both high-symmetry directions (certainly superior to the other EAM potentials).

There are clearly many more subtleties in the analysis of these dispersion curves. However, the present work seeks to present the equivalency of approach between single-crystal and polycrystalline neutron scattering, and hence further discussion is not relevant to the present objective.

2.4. Interpretation of one-phonon polycrystalline coherent S(Q, ω)

The present approach assumes that the one-phonon coherent scattering process is dominant in the studied system at low Q; for the aluminium system this is a reasonable assumption given that aluminium is a strongly coherent scatterer [with a coherent cross section of 1.495 b (1 b = 100 fm²), contrasting significantly with the incoherent cross section of 0.0082 b]. The approach also assumes no preferred orientation of crystallites in the sample, as it uses spherical polycrystalline averaging (although intensity changes due to preferred orientation are readily introduced by altering the sampling method): again a reasonable assumption for a polycrystalline cubic system such as aluminium. The resulting contour plot of the poly-CINS intensity for the fitted LJ 12–6 potential is shown in Fig. 3, which was obtained using the Scatter subroutine in the GULP program as described above. This poly-CINS plot is a 300 (in Q) × 300 (in frequency or energy transfer, E_T) bin data set with 300 angular steps in θ and φ, for ranges of 0.0 ≤ Q ≤ 10.0 Å⁻¹ and 0 ≤ ω ≤ 350 cm⁻¹ (0 ≤ E_T ≤ 43.4 meV). This produces a sampling mesh of 27 million q points and samples (Q, ω) space in an approximately equivalent Q and energy transfer resolution to that provided by time-of-flight instruments such as MARI. The pattern is clearly complex but can be analysed if approached systematically in the light of the experimental or calculated dispersion curves.

Figure 3 Theoretical polycrystalline S′(Q, ω) for aluminium, calculated using the LJ 12–6 potential model, for the full range of Q (0 ≤ Q ≤ 10.0 Å−1) and ω (0 < ω < 350 cm −1). The S′(Q, ω) intensity rises from very low (dark blue) through mid (light blues and yellow) to very high (dark red). White areas denote regions in (Q, ω) space where no scattering occurs, whereas dark blue shows low-intensity scattering due to off-symmetry direction (polycrystalline averaged) scattering.

Fig. 4(a) shows the dispersion surface for the first mode (in this case, the longitudinal acoustic mode) overlaid with a colour map that shows the S(Q, ω) intensity for the plane (hk0) over the range of the calculation. Fig. 4(b) takes this projection and rotates it so that the (h00) dispersion surface is visible (equivalent to the allowed scattering from the longitudinal mode in the [200] direction), so that the coherence condition is illustrated; from here, one can clearly see the regions of allowed scattering [with the colour map providing S(Q, ω) intensity information – white effectively denotes regions of (Q, ω) space where there is no allowed scattering]. From Fig. 4(b), one can clearly see the regions of intense scattering around the Brillouin zone boundaries, as well as the increased intensity corresponding to the 1/ω term in equation (5). Fig. 4(c) shows the same data, as seen from `above', viewing the (hk0) plane; this figure rather clearly illustrates the periodic boundary conditions and provides a reference point for Fig. 4(d). The white line denotes the vector from the (000) point in the reciprocal lattice out to the (420) point.

Figure 4 Views of the mode 1 dispersion surface in the QxQy plane of the reciprocal lattice of aluminium, using the original Lennard-Jones potential (before fitting has been applied), with scattering intensity superimposed upon the frequency surface as a colour map. (a) An isometric projection of the dispersion surface. (b) A cross section through the plane from the Qx-axis perspective. (c) The view looking down on the plane. (d) A diagrammatic representation of the (hk0) plane in aluminium, showing for example the [420] direction (broken line). The two spheres in Q show the upper and lower values of Q for which one-phonon scattering can occur as a result of the condition |τ − q| < Q < |τ + q|.

Fig. 4(d) provides an illustration of how it is that some of the sharp features are associated with vectors to more remote reciprocal lattice points. The diagram shows the (hk0) plane in reciprocal space and for a particular value of ω that cuts the LA dispersion surfaces close to each `allowed' f.c.c. reflection, out as far as (420). Thus the small circles represent the q vectors corresponding to the LA phonons at that value of ω. Because of the coherence condition, the sphere in Q, which has to be integrated over direction to yield the intensity expected in the polycrystalline case, has to lie in the range defined by |τ − q(ω)| < Q < |τ + q(ω)|. Thus we expect to find sharp features for this value of ω where the Q sphere touches one of the small circles as illustrated, and this turns out to be along the vectors from the origin to the higher reciprocal lattice points. Noting this, and taking into account the polarization term in the intensity e_ds·Q, the edge features in the scattering will be pronounced for LA modes because here the phonon displacement vector is parallel to Q. Transverse modes, on the other hand, will tend to peak where the Q sphere passes through the reciprocal lattice point, as here the displacement vector is parallel to the Q vector at the point where the sphere crosses the dispersion surface at right angles (and also passes through the reciprocal lattice point). Because the steps in intensity generally occur along the [hkl] directions, they are relatively easy to identify in the integrated one-phonon cross section.

The process presented here is a simple one; reciprocal lattice vectors from the origin of the reciprocal lattice to the first 11 reciprocal lattice points are calculated for the model used in the theoretical generation of S′(Q, ω) – namely the Lennard-Jones 12–6 model introduced in §4. These lines are used to calculate S′(Q, ω) going through the different (hkl) points. As expected, the cross section shows a sharp intensity step where the two spheres touch tangentially (in the longitudinal case) or peak at the (hkl) point (transverse case). This provides an initial qualitative appreciation of the features found in the poly-CINS data (as discussed in §3). Further clarification, in the form of figures demonstrating this curve projection and overlay process, is provided in the supplementary text¹ (Fig. S5).

The next step in this process is to take cuts through the calculated polycrystalline S(Q, ω) data for given ω intervals integrated over a narrow band of Q values and to associate, where possible, distinct scattering features with individual dispersion surfaces in the symmetry directions selected. In Fig. 5, cuts of constant Q (having a single `bin' width of 0.0334 Å<sup>−1</sup>) have been taken through the theoretical data presented in Fig. 3. Each cut, which is representative of the Q resolution available from a typical high-resolution chopper spectrometer, is then inspected and the most prominent features are compared with the equivalent projections of the dispersion curves. It is observed that the steps in intensity at a given Q tend to occur where this cut crosses one of the set of `dispersion' curves calculated along higher-order τ directions, as explained above. As noted above, the intensity features observed can be classified in terms of either peaks or coherence edge features; both sets of features are determined by the structure and vibrational characteristics of the material and are governed by equation (4). For the purposes of this work, it is unnecessary to identify every feature in a given cut through the poly-CINS data set, because clearly some will arise where the Q sphere touches the dispersion curve away from any symmetry direction.

Figure 5 Identification of prominent features in the theoretical poly-CINS data set presented in Fig. 3. The horizontal axes are energy transfer and vibrational frequency (meV and cm−1, respectively) and the vertical axis is S′coh(Q, ω). Major scattering features are labelled for each cut in terms of a q point along the direction in the conventional reciprocal lattice [hkl]. Black arrows denote an identified feature, with appropriate [hkl], in the LJ 12–6 theoretical data and grey arrows denote prominent features that do not correspond to any of the dispersion curves used in this analysis.

In this work, coherence edge features have generally been selected for identification, as the use of experimental data requires the summation of adjacent Q bins to reduce the statistical error in the measured intensity (owing to the relatively low count rate for a given set of detectors). This results in a `smearing' of both types of sharp feature such that the peak–coherence edge paired features are often the only readily identifiable feature in a given cut through an experimental set. Therein lies the compromise implicit in this approach to the analysis of poly-CINS data; a narrower range of Q over which a summation is taken results in sharper Q-dependent features, but this in turn reduces the number of measured neutron counts and hence the statistical accuracy of the data. In the extreme, a full summation over the entire range of Q sampled by an instrument results in the effective application of the incoherent approximation; here all Q dependence is lost and the data collection is reduced to a phonon density of states measurement, whereas a fine cut (as for a single detector), providing the best Q resolution, would result in excessively long measurement times to gain sufficient statistics to make an effective comparison with a model. Examples of coherence edge features in Fig. 4 include the features containing the [111] LA modes at Q = 1.0 Å⁻¹ and Q = 3.4 Å⁻¹ and the [200] TA coherence edge at Q = 1.8 Å⁻¹, for energy transfers of 33.8 meV (273 cm⁻¹), 29.8 meV (240 cm⁻¹) and 38.6 meV (311 cm⁻¹), respectively.

It should be noted that the full intensity of S_coh′(Q, ω) at a given (Q, ω) value is not exclusively the result of a single mode in a set direction in reciprocal space. Clearly, a large number of q values contribute to a given S_coh(Q, ω) intensity after averaging over Q directions. However, it does seem that many of the sharp features in the scattering functions do arise from the tangential intersection of the sphere in Q with a particular dispersion curve.

2.5. Bulk properties

Here we present the bulk properties calculated from the models described in the previous section. The values are given in Table 2, along with experimental values from the literature. Note that the bulk moduli calculated with GULP use the Voigt volume derivative approach (Nye, 1957).

As shown in Table 2, the potentials all perform adequately when compared with experiment; the single exception to this is the binding energy predicted by the LJ 12–6 pair potential. As is to be expected, this two-parameter LJ model is unable to fit the binding energy, lattice parameter and mechanical properties simultaneously. Because of its pairwise nature, the LJ 12–6 potential cannot capture the Cauchy violation between the elastic constants C₁₂ and C₄₄, unlike the EAM models. However, this simple model, when fitted to the elastic constants, provides good agreement across a range of other bulk properties, in particular, the bulk moduli; the model predicts Young's modulus especially well compared with the other models. It also performs adequately for the bulk and shear moduli, although both the NP-B and Sutton–Chen potentials do better, with the Mei–Davenport outperforming the Lennard-Jones by a considerable margin. However, the Lennard-Jones model performs very well in the prediction of Poisson's ratio; the EAM models all predict values that are significantly different from experiment. No particular conclusions should be drawn from the agreement with elastic constants as these were used to parameterize the model. Thus, on the whole, the simple LJ 12–6 model performs remarkably well with respect to the curvature of the potential energy surface; the Mei–Davenport model generally matches, or slightly exceeds, its performance for most of the bulk properties compared here, while the Sutton–Chen and NP-B potentials generally have a worse overall performance in this regard.

When comparing the potential models it is important to consider the relative computational expense, given that calculations of poly-CINS will require many second-derivative evaluations. As an example, the LJ 12–6 model completes a standard sampling of (Q, ω) space, as described in §2.4, about 300 times faster than the equivalent EAM calculations. To be precise, the LJ 12–6 model takes around 150 s on a 8-core, 3 GHz Xeon workstation, whereas the EAM potentials average around 45 000 s on the same workstation for the identical sampling and phonon calculations; it is thus clear that the LJ 12–6 model can be useful as a tool for generating the bulk properties in systems with large numbers of atoms in the unit cell, although its poor binding energy and more limited transferability to other environments, such as cluster calculations, limit its broader utility.

4.1. Comparison of experimental Al poly-CINS S′(Q, ω) data with model predictions

As noted above, the full intensity of S_coh′(Q, ω) at a given (Q, ω) value is a superposition of the scattering seen in all directions. That is why it is necessary to concentrate on the identification of particular sharp features for the comparison of experiment and theory. Once S_coh′(Q, ω) features are identified as being associated with a given cut in reciprocal space, the next step is to approach the experimental S(Q, ω) data and attempt to identify equivalent features. In order to facilitate the comparison, both experimental and theoretical cuts (the LJ model) through the data sets at fixed Q values may be superimposed as in Fig. 7.

Figure 7 Selected cuts at constant Q through the experimental S′(Q, ω) (black line) for aluminium at 10 K obtained on the MARI spectrometer, ISIS, from Q = 1.0 Å−1 to Q = 7.0 Å−1. The horizontal axes are energy transfer and vibrational frequency (meV and cm−1 respectively) and the vertical axis is S′coh(Q, ω). The width of cut is 0.067 A−1 and the corresponding cut through the LJ 12–6 theoretical data (fitted to elastic constants) is given as the red line. All intensities are to scale.

We note here that there are gaps in the detector coverage on the instrument and these affect the choice of constant Q cuts. Hence a new set of cuts, chosen to pass through the sharpest, most intense one-phonon features with a minimum of gaps due to missing detectors, were selected: cuts were made through both theoretical and experimental data sets for a bin width of 0.0667 Å⁻¹ (median value ±0.03335 Å⁻¹) for median values of Q of 2.2, 2.5, 3.2, 3.6, 4.2, 4.6, 5.0, 5.6, 6.2, 6.6 and 7.0 Å⁻¹. The resulting comparisons are shown in Fig. 7.

Although there are significant differences in both the intensity profiles and the positions of sharp features on the energy transfer scale, the general S_coh′(Q, ω) profile is in reasonable agreement: sufficiently so to relate features in the theoretical and experimental profiles.

From these comparisons, 31 S_coh′(Q, ω) features could be reasonably assigned to one of the 11 reciprocal space directions used for this treatment. In order to reduce the likelihood of assignment errors in this process, a Python script was written to automate the selection process somewhat; each potential matchable feature in the experimental data (whether peak or coherence edge) was selected directly from the relevant data slice and the corresponding energy transfer for the feature was recorded; these values were then used as sort parameters. This sort generated a list of the nearest theoretical dispersion surfaces in our set of [hkl] directions, and only surfaces that passed through the feature within 1 cm⁻¹ (Δω) were considered as potential matches. Depending on the relative sharpness of the scattering feature, some features of less than 1 cm⁻¹ were discarded as being insufficiently clear to match. Each sort then provided the dispersion curve label, the q point (in terms of fractional reciprocal lattice vector) and the mode number (using the mode identification in GULP) for use in model fitting, assuming that the Δω condition was met and the feature was sufficiently distinct in both theoretical and experimental data sets.

This process is clearly amenable to automated feature identification via a mathematical optimization formalism. However, for this initial work, the same process as is used for mode assignment in other spectroscopy has been used and only clearly distinct features have been selected for potential comparison to experimental data.

With these criteria, of the 31 identified features in 11 cuts through the Lennard-Jones-derived data, only 20 could be unambiguously assigned to the experimental data. The labelling is provided in Fig. 8 for these 20 features, where the arrows are labelled with the relevant direction in q space. The upper values (black) refer to the experimental data and the lower values (red) to the model. To aid in the visualization of these points, Fig. S5 (in the supplementary text) shows how the sampling of (Q, ω) space has been accomplished, by projecting the points labelled in Fig. 8 onto the Q scale used for Figs. 3 and 6.

Figure 8 Four constant Q cuts through Fig. 3 (red line) and Fig. 7 (black line) for a Q bin of width of 0.067 Å−1. The horizontal axes are energy transfer and vibrational frequency (meV and cm1, respectively) and the vertical axis is S′coh(Q, ω). Major scattering features are labelled for each cut in terms of a point along the direction in the conventional reciprocal lattice [hkl]. Red arrows (below spectra) denote an identified feature, with appropriate [hkl], in the LJ 12–6 theoretical data and black arrows (above spectra) the equivalent feature in the MARI data. Relative intensities between cuts are not to scale, for clarity of presentation.

The final step in the analysis process involved fitting two of the models (LJ and Mei–Davenport) to these (q, ω) points using GULP's internal least-squares minimization routine. In this procedure, the (q, ω) points were input as observables and the optimal parameters were obtained for both models from a variety of initial values to ensure that a reasonable global minimum was obtained. For the Mei–Davenport model, the EAM density terms were not fitted, although the lattice was allowed to relax in one fit and fixed in the other to explore the effect of fixing the lattice in such a model.

4.2. Results from the fitting of poly-CINS data to two models for aluminium

The fitting process proved very successful for the case of the Lennard-Jones potential model, and a global minimum was found with values of A and B of 28273.896 eV A⁻¹² and 46.590 eV A⁻⁶, respectively, keeping the lattice constant fixed. The fitting process applied to the Mei–Davenport model, whilst successful, was considerably more methodologically dubious as the parameter space for the process is considerably larger and, as this work is not specifically targeted at producing a more physically accurate MEAM model, little effort was spent on ensuring that a true global empirical minimum was reached. However, as the EAM density parameters were kept fixed, i.e. were not included as fitting parameters, the fit resulted in changes to the E_c, α, β and γ parameters (with new values of 3.335, 4.57, 7.047 and 11.326 eV, respectively) in the EAM functional part of the potential, with φ₀ and δ changing to 0.1330 and 7.3866 eV, respectively. The final parameterization of each model is presented in Table 3.

Thus, in Fig. 9, the initial and final (fitted) versions of the Mei–Davenport and Lennard-Jones models were used to generate S_coh′(Q, ω) data sets equivalent to those found in Fig. 3, and constant Q cuts were taken through these data sets, following the process described in the previous section. The figure presents a representative example [for median Q = 4.6 Å⁻¹, with a cut width of 0.0667 Å⁻¹ (median value ± 0.0334 Å⁻¹)] of these data comparisons; more have been provided in the supplementary text. As can be seen, the key features being tracked are the peak corresponding to the [531] dispersion curve at 145 cm⁻¹ (18.0 meV) and the coherence edge feature corresponding to the [422] dispersion curve at 200 cm⁻¹ (24.8 meV) in the experimental data. Curves (a) and (c) show the theoretical S_coh′(Q, ω) generated from the initial versions of the models and clearly illustrate the better agreement with experiment provided by the LJ model. Curves (b) and (d) are the equivalent S_coh′(Q, ω) data generated after the fitting procedure It is clear that both models show significant improvement; in particular, the peak corresponding to the [531] direction shows much improved agreement with the experimental data. This is not surprising given that the features discussed were used as observables in the fitting process. However, selection of other cuts also produces features that are in better agreement with experiment (see supporting text for additional examples).

Figure 9 Comparison of four theoretical models, using the constant Q cut (width of 0.067 Å−1) for Q = 4.6 Å−1 from Fig. 8, with experimental data for aluminium at 10 K obtained on the MARI spectrometer, ISIS (grey line). (a) The original LJ 12–6 model, (b) the LJ 12–6 model fitted from MARI experimental data, (c) the original Mei–Davenport model and (d) the Mei–Davenport model fitted from MARI experimental data. The horizontal axes are energy transfer and vibrational frequency (meV and cm−1, respectively) and the vertical axis is S′coh(Q, ω).

At this point in the analysis, it becomes clear that the present process lends itself very naturally to an iterative approach to the fitting process; although the present treatment deals with only a single `run through' of the method, the most sensible means of improving fits [and hence the quality of the model generating S_coh′(Q, ω)] would be to take the outputs of the current method and, rather than moving straight to bulk properties and dispersion curves, to re-apply the process (probably several times) by taking cuts through the data set generated by the new model(s) and running through the feature identification and the fitting steps again. This approach, which would resemble a profile refinement process as used for diffraction data (in effect, inelastic profile refinement), would minimize the differences between the theoretical and experimental S_coh′(Q, ω); work is in progress to demonstrate this approach.

Once the fitted models have been inspected for agreement with experiment, the final stage in the analysis is that of generating bulk properties and dispersion curves for the original and fitted models. Fig. 10 presents the dispersion curves for the two versions of the Lennard-Jones and of the Mei–Davenport models compared with the single-crystal dispersion curve data of Stedman & Nilsson. Rather encouragingly, both fitted potential models generate dispersion curves that are very similar, illustrating that the sampling of reciprocal space is consistent for both models. Both of the fitted models also produce dispersion curves that are in better agreement with the experimental curves, after allowing for the difference in temperature: the Stedman & Nilsson data were taken at 80 K, whereas the models generated are for data taken at 10 K. The higher temperatures will result in slightly softer modes and hence lower maximum frequencies at the zone boundaries. Of course, none of the models effectively reproduce the curvature of the TA modes in the [110] direction: both models have very short cutoff distances for the interactions (first nearest neighbour for the LJ model and fourth nearest neighbour for the Mei–Davenport model), which will significantly influence the curvature of the dispersion curves in this region. Indeed, the work by Gilat & Nicklow (1966) suggests that effective Born–von Karman force constant models in metals such as aluminium are sensitive to nearest neighbour interactions out to at least the eighth nearest neighbour distance. However, both models do show an improved agreement with experiment (both for the single-crystal values and for the data reported in the present work).

Figure 10 Dispersion curves calculated for the semi-empirical models fitted to experimental data in this work, compared with the experimental triple-axis spectrometer data (red points) previously presented in Fig. 3. Heavy black lines are the original LJ 12–6 model, thin black lines the fitted LJ model, thick grey lines the original Mei–Davenport model and thin grey lines the fitted Mei–Davenport model.

Finally, the bulk properties of aluminium were calculated for both fitted models. The results are presented in Table 4. The fitted Lennard-Jones model, which produces improved dispersion curves, nevertheless performs somewhat less well than the original model as far as the bulk properties are concerned. This is unsurprising given that the initial model was fitted to experimental elastic constants, but changes to the force constants A and B are relatively small. The bulk property calculations for the Mei–Davenport model were handled in two ways; the first was a straight fixed-lattice calculation where the potential generated very good agreement with experimental data; in the case of binding energy (not strictly valid for fixed-lattice calculations), Young's and shear moduli, and elastic constant predictions, the fitted model outperforms the original model and generates predicted bulk properties consistently closer to experimental values. With the constraint of a fixed lattice removed, the model fitted to the S_coh′(Q, ω) data produced a second set of predicted bulk properties (in parentheses in Table 4). Although this results in a relaxation of the lattice, giving rise to a lattice constant that is significantly too large (4.17 Å, rather than the experimental value of 4.05 Å), the model performs much better than either the Lennard-Jones (fitted) or the original Mei–Davenport model in terms of predicted binding energy and the other bulk properties, especially the elastic moduli (Young's, bulk and shear). We have demonstrated that the results can be markedly improved simply by expanding the cutoff of the LJ 12–6 model to 12.0 Å. This results in a model that provides broadly similar agreement (in terms of bulk values) to that of the original LJ model (fitted from elastic constants), yet requires no adjustment of the lattice constants (i.e. the model predicts a lattice spacing of 4.05 Å when allowed to relax). The resultant values of the parameters are included in Table 3 but further discussion is postponed.

4.3. Discussion on the extension of the method to other systems

As has been stated earlier, aluminium was chosen to illustrate the methodology for this work because it has the simplest possible crystalline structure as well as being a very well understood material in terms of both bulk properties and dynamics. Given the complexity of polycrystalline data sets, aluminium represents the simplest possible case to apply in terms of both basis size and symmetry, yet for this method to be generally useful, it should be extensible to materials with polyatomic basis sets and should also provide some demonstrable advantages to the current method of analysing powder spectra – namely the incoherent approximation.

Currently, the standard approach to assigning vibrational frequencies for polycrystalline coherent scattering systems is via the so-called incoherent approximation, a detailed treatment of which can be found elsewhere (Mitchell et al., 2005; Kearley, 1995). In this approach, the experimental data are integrated over the full angular range of detectors, which provides greatly improved statistics at the cost of obscuring all explicit Q dependence in the resulting two-dimensional (frequency versus integrated intensity) data sets. The general method effectively treats the resulting data as a means of experimentally determining the phonon density of states, g(ω). These data are then compared, with minimal processing, with a gamma point calculation [typically using DFT and software such as PHONON or a-CLIMAX (Ramirez-Cuesta, 2004) to post-process the force constant outputs into simulated inelastic neutron intensity data], and some implicit Q dependence is then inferred from relative intensities or the intensity profile as a whole. As an analysis method, it has much to recommend it: the method is very computationally efficient (a gamma point calculation is relatively computationally inexpensive and can be performed on a desktop workstation in very little time for small-unit-cell systems) and, as has been mentioned, there are a number of freely available support software packages available to assist in this analysis. However, it is clear that there are several issues with this approach, the most significant being that explicit Q dependence of the vibrational modes is lost entirely; as one is dealing with the density of vibrational states, one may not track the curvature of individual modes. Indeed, before the computational resources became available for routine DFT calculations, much of the most detailed inelastic scattering simulation and fitting used semi-empirical models and carefully considered correction factors (Egelstaff & Poole, 1969) to properly weight the integrated intensities. The scattering data were plotted as a function of Q² at a given angle, and the high-Q data were extrapolated back to yield a gradient at small Q², where the actual data shows large fluctuations due to coherent terms. This would result in semi-empirical force constant fits that could be very difficult to interpret and assign properly, given the sensitivity of the fits to the relative intensity profiles (Kearley, 1995).

After the advent of the easily accessible computational resources required to directly generate intensities using DFT, the emphasis shifted to using the aforementioned DFT direct simulation approach, typically compared with directly integrated g(ω). However, this approach directly integrates the scattering over observed values of Q at a given energy and assumes that the coherent scattering averages out. Our calculations show that there are significant differences between the actual density of states obtained from GULP and the above quantity obtained from the GULP poly-CINS output. The most notable one is that of intensity differences between the strict incoherent density of states, especially at low Q, where contributions from the coherent scattering in this region produce a `summed up over Q/angles' profile for the incoherent approximation that significantly deviates from the density of states. There are also issues associated with fitting an improved model: DFT calculations do not, in general, provide precise matches to INS data sets, and the scaling approach (Mitchell et al., 2005) used to assign modes unambiguously can obscure the quality of a given calculation. In any case, DFT outputs cannot be `fitted' to provide functional models for T > 0 K systems with ease. The poly-CINS method does not suffer from this limitation (although DFT inputs can be used to provide an initial starting point for finite temperature calculations), as the Q dependence of individual modes can be identified and tracked, without resort to either complex correction factors or scaling of frequencies.

As the size of the basis set increases from the monatomic basis used for this work, other features in the scattering data will become relevant to discuss – most notably the scattering from optic modes (as aluminium is monatomic, it does not possess optic modes). Although this work has restricted itself to the discussion of the dynamics of the aluminium system, and by definition scattering profiles derived from acoustic modes, the authors have measured a number of polyatomic systems (with lower symmetries than cubic aluminium) using this approach, most notably graphite (Roach, 2006; Roach, Heuser et al., 2013; Roach, Parker et al., 2013), MgD₂ (Buckley et al., 2013) and C₆₀ (Roach, 2006; Roach, Heuser et al., 2013; Roach, Parker et al., 2013). In all these cases, optic modes generate the same coherence edge and peak features (they are still subject to the same selection condition as acoustic modes) and can be measured and identified, although these can be more difficult to distinguish than in the present case, requiring extremely long data collection runs on high-intensity instruments to provide sufficiently high count rates to distinguish these features from noise. This is especially so in the case of very large systems and systems with relatively `flat' optic mode branches (such as C₆₀), which require correspondingly high resolution sampling in the calculation of the poly-CINS intensities. Lower-symmetry systems also appear to pose no particular problem, providing the sampling of reciprocal space is sufficiently tight.

Finally, zone boundary effects can add to the variation of intensities, and one might speculate that this issue might affect the identification of edge and peak features where scattering close to the zone edge is very much more intense (see Fig. 4b and comments in §2.4); indeed, it is very likely that a number of the most intense features in Figs. 7 and 8 are due to the orientational averaging of this effect. This is, however, more likely to be an issue with samples with crystallites of higher-symmetry materials (such as aluminium), as the Brillouin zone path is very simple and these effects will superimpose in the orientational averaging much more obviously. With lower-symmetry crystallites, this would probably average out into a smoother intensity profile. However, it is important to check on this. Fig. S5 in the supplementary text provides a convenient method of checking for bias introduced as a result of this effect, as well as a means of checking other sampling bias (TA rather than LA, for instance, or zone centre versus zone edge). In the case of aluminium, and the sampling and feature selection for this work, it appears that the sampling is evenly split between zone edge and other regions. It is quite clear that some coherence edge features are more pronounced near the zone edges, but it is also clear (from Figs. 8 and S5) that scattering beyond these areas is sufficiently intense to identify these features away from the zone edge.