1. Introduction

In the last decade, important developments in single-crystal high-pressure X-ray diffraction experiments (Merlini & Hanfland, 2013; Kantor et al., 2012; McMahon et al., 2013) led to the discovery of completely new characteristics in the phase diagrams of the elements. These developments have shown that a surprising degree of complexity exists in the structures of some elements and in their physical behaviour at high pressure (McMahon & Nelmes, 2006; Degtyareva, 2010; Fabbris et al., 2015). This provides a rich testing ground for fundamental physics, chemistry and material sciences.

Many recently reported crystal structures of elements at high pressure (McMahon & Nelmes, 2006; Degtyareva, 2010) are not only very complex but, in addition, often lose their three-dimensional periodicity (Loa et al., 2012; Nelmes et al., 1999; McMahon & Nelmes, 2004a; McMahon et al., 2000, 2006, 2007; McMahon, Rekhi & Nelmes, 2001; Lundegaard et al., 2009; Degtyareva, McMahon & Nelmes, 2004a; Schwarz et al., 2003). This means that any structural description using the classical approach can result in crude and inappropriate approximations (Loa et al., 2012; Nelmes et al., 2002; McMahon, Nelmes & Rekhi, 2001; Degtyareva, McMahon et al., 2004). The real challenge is to recover the correct symmetrical properties hidden behind the complexity of the diffraction patterns, in order to reveal their detailed and true atomic arrangement (McMahon et al., 2007; Schwarz et al., 2003; Perez-Mato et al., 2006).

Barium is an interesting and very typical case of structural complexity. It exhibits a pressure-dependent structure evolution from a body-centred cubic (b.c.c.) phase (Ba I at P < 5.5 GPa), followed by a hexagonally close-packed (h.c.p.) phase (Ba II at 5.5 < P < 12 GPa), followed by the very complex so-called host–guest (H-G) structure of Ba IV (Loa et al., 2012; Nelmes et al., 1999; McMahon & Nelmes, 2004a), which is an equilibrium phase stable between 12 and 45 GPa at room temperature (Loa et al., 2012; Nelmes et al., 1999; McMahon & Nelmes, 2004b; Kenichi, 1994). The H-G structure has been described as an incommensurate composite model with two interpenetrating H and G substructures, similar to many other elements at high pressure (Nelmes et al., 1999; McMahon & Nelmes, 2004a; McMahon et al., 2000, 2006, 2007; McMahon, Rekhi & Nelmes, 2001; Lundegaard et al., 2009; Degtyareva, McMahon & Nelmes, 2004a; Schwarz et al., 2003). There is a clear differentiation between atoms forming the H framework and the G atoms forming chains located in parallel channels.

Unlike other elements, Ba IV exhibits extremely elaborate pressure-dependent transformations of the H-G structure. With increasing pressure, phases Ba IVa, Ba IVb and Ba IVc have been identified (Loa et al., 2012; Nelmes et al., 1999; McMahon & Nelmes, 2004a). Precise structural characterizations of these phases are missing or incomplete. The Ba IVa structure has been solved by considering separately the H and G partial structures using a three-dimensional model for each of them (Nelmes et al., 1999; McMahon & Nelmes, 2004a). For the most complex phase of Ba IVc, the authors proposed a three-dimensional periodic model including 768 atoms in a supercell approximation with 72 times the volume of the basic host unit cell including 99 independent Ba atoms (Loa et al., 2012). In principle, this implies the existence of an equal number of different electronic states, which simply looks unrealistic. Resolving the precise structures of these barium phases is therefore a key point in order to understand better the behaviour of metals under high pressure.

The degree of complexity of Ba IVc (Loa et al., 2012) is not comparable with the proposed H-G model of Ba IVa (Nelmes et al., 1999; McMahon & Nelmes, 2004a), with two small subcells and only two independent atoms. While the strategy of adopting a three-dimensional superstructure model to approximate the effects of modulation and the presence of satellite reflections is commonplace, the above example demonstrates that the structural complexity can quickly become unmanageable.

From previous studies of Ba high-pressure (HP) phases, it appears that no crystallographic data are available for Ba IVb and its structure is still unresolved. In order to shed light on the unknown HP phase Ba IVb, we collected a sequence of single-crystal diffraction intensities at room temperature using synchrotron radiation in the pressure range between 16.5 and 21.8 GPa, where Ba IVb is stable. For each pressure, all reflections were indexed in terms of a single incommensurately modulated structure, thus leading to a structure solution within the (3+1)-dimensional superspace symmetry approach. [In the following, the terminology described by Janssen et al. (2007) will be used.] With the example of Ba IVb, we show that a systematic analysis of the indexed reflections allows different models for the H-G structures. For the first time we consider the incommensurately modulated (IM) model along with the incommensurate composite, which is usually applied for H-G structures (Nelmes et al., 1999; McMahon & Nelmes, 2004a; McMahon et al., 2000, 2006, 2007; McMahon, Rekhi & Nelmes, 2001; Lundegaard et al., 2009; Degtyareva, McMahon & Nelmes, 2004a; Schwarz et al., 2003). Tests of the models clearly favour the IM one for Ba IVb. The IM structure of Ba IVb reveals a density wave in the channel atoms (G substructure) which is pressure-dependent. This wave is created by the shift of atomic positions in the crystal bulk, which evolve towards a uniform distribution at higher pressure. For comparison, this wave is absent in the similar structure of Rb IV (McMahon, Rekhi & Nelmes, 2001), which was solved as a composite with periodic H and G sub­structures. The IM model exhibits the unique property that it can generate a unified and consistent series of structural models of the same or other compounds at different pressures, and hence can provide a tool for structure prediction (Arakcheeva & Chapuis, 2008).

2. Experimental

3. Results

In our experiments, two different diffraction ranges can be distinguished between 16.5 (1) and 21.8 (1) GPa. The phase described by Loa et al. (2012) as Ba IVc is observed above 20 GPa together with Ba IVb, which is a single phase below this pressure. Disparity with the pressure range of 18–21 GPa previously published for Ba IVc is almost certainly due to the neon gas pressure-transmitting medium used for the first time in the present Ba IV study.

Structure solutions of Ba IVb at 16.5 (1), 17.4 (1), 18.2 (1), 18.5 (1), 19.0 (1) and 19.6 (1) GPa are reported and discussed below.

3.1. Reciprocal space and superspace symmetry

The complete interpretation of the diffracted intensities is illustrated in Fig. 1 with the diffraction measurements obtained at 19.6 (1) GPa. The whole set of reflections was indexed as hklm with the wavevector H = ha*+ kb* + lc* + mq using lattice parameters a ≃ b ≃ 11.5 Å and c ≃ 4.6 Å and the incommensurately modulated vector q = βb* + γc* ≃ 0.1b* + 1.36c*. The strong hkl0 reflections are considered the main ones; all others hklm (m ≠ 0) are satellites. The index m = 1, 2 and 3 corresponds to three orders of satellites observed by diffraction (Fig. 1).

Figure 1 Reciprocal-space sections measured at 19.6 (1) GPa containing (a) 0klm and (b)–(g) hklm reflections. White, dark-blue, turquoise and orange circles indicate the main reflections and first-, second- and third-order satellites, respectively. The special characters in part (a) refer to the corresponding lines in the other panels. All reflections are indexed by the reciprocal-lattice vectors H = ha* + kb* + lc* + mq, with q = βb* + γc* [yellow arrows in part (a)]. In parts (c) and (d), the a*b* reciprocal lattice plane (white square) is defined by the strong main reflections hk30 and hk40. In parts (b), (e), (f) and (g), the satellites indicated by circles belong to independent reflections related to others by the (110) and (010) twinning planes (dashed white lines).

Despite the tetragonal character (Figs. 1c and 1d) of the main reflections, the refined lattice parameters point to a lower symmetry (Fig. 2a). For all six measurements, averaging of the reflection intensities shows unacceptable reliabilities of R_int ≃ 0.55 for each group of symmetry-equivalent reflections. An improved reliability with R_int = 0.04–0.14 was obtained in the monoclinic system with the unique axis a. The pseudo-tetragonal appearance of the reciprocal-space patterns (Fig. 1) can be understood as a consequence of twins linked by the (010), and (110) mirror planes inherited from the tetragonal Ba IVa modification stable at lower pressure (Nelmes et al., 1999; McMahon & Nelmes, 2004a).

Figure 2 Pressure dependence of the unit-cell parameters and components β and γ of the modulation vector q = βb* + γc*. (a) The a and b parameters are sensitive to pressure, while c is rather stable, c = 4.61 ± 0.02 Å. (b) The unit-cell volume ratio relative to the phase at ambient temperature and normal pressure. (c) The β component of the vector q changes from 0.06 ± 0.002 to 0.115 ± 0.010 between 17.4 (1) and 18.5 (1) GPa. (d) The γ component is stable, with a value equal to 1.36 ± 0.005.

Using the refined lattice parameters and components of the modulation vector q (Figs. 2a, 2c and 2d), the integration of experimental intensities was performed for the six diffraction data sets. For each pressure, about 18 000 reflections were used for the structure solution and refinement, of which 600–700 had I > 2σ(I).

The (3+1)-dimensional monoclinic superspace group P2₁/b(0βγ)00 was derived from the observed systematic extinctions.

3.3. The density wave and its pressure-sensitive evolution

The IM model reveals an essential and specific feature of the Ba IVb phase, namely the presence of a density wave in the channels of the structure (Fig. 3). This wave arises from the nearest Ba_ch—Ba_ch distance variation in the channels (Fig. 4, and Section S3 in the supporting information). 70–85% of these distances are in the range 2.9–3.8 Å (Figs. 4a and 4b), forming dumb-bells and triplets along the channel (Figs. 4b and 4c). This results in dense and sparse arrangements of the Ba_ch atoms, forming a wave in the bc layers (Figs. 3b and 3c). This wave changes with pressure, increasing from 16.5 to 19.6 GPa towards the formation of a more uniform chessboard-like distribution of the dense and sparse regions in the bulk of the crystal (Figs. 3d and 3e). The pressure dependence of the unit-cell parameters (Figs. 2a and 2b), and especially of the β component of the modulation vector (Fig. 2c), confirms this pressure-sensitive structural evolution appearing between 17.4 (1) and 18.2 (1) GPa.

Figure 3 The incommensurately modulated structure Ba IVb. Both Bafr (grey) and Bach (blue) atoms are subject to positional modulation. The structure is periodic along the a axis and aperiodic in the bc planes. (a) A portion of the structure given in the ab projection, illustrating the weak modulation of all the atoms in the a and b directions. (b) and (c) The bc projection of a layer of thickness a at (b) 19.6 (1) and (c) 16.5 (1) GPa. The projection shows that the main structure modulation concerns the displacements of Bach atoms along the c axis, i.e. along the channels formed by Bafr atoms. The displacements induce variation in the Bach—Bach distances. The orange sticks link atoms distant by 2.90 to 3.8 Å, showing a wave of dense and sparse arrangements of Bach atoms. (d) and (e) The alternating distribution of the layers shown along the a axis at (d) 19.6 and (e) 16.5 GPa. Bafr atoms have been omitted to highlight the chessboard-like distribution of dense and sparse regions.

Figure 4 Statistical analysis of the Bach—Bach distances in the channels. (a) and (b) t-Plots of the closest Bach—Bach distances and their statistical distribution at (a) 16.5 and (b) 19.6 GPa. Each solid line corresponds to a distance varying between 2.9 and about 7 Å. The domain intervals indicate one (dark grey) and two (light grey) interatomic contacts associated with the formation of dumb-bells and triplets, respectively, in the 2.9–3.8 Å range. (c) The pressure dependence of the dumb-bell and triplet content.

4. Discussion

A key point of our new results concerns the measurement, interpretation and indexing of hklm reflections with l ≠ 0 and m ≠ 0 (for instance, in Fig. 1). Despite having much weaker intensity than the strong hkl0 main reflections, this group concerns up to 30–50% of the measured reflections in our experiments (Fig. S1 in the supporting information). The existence of these reflections was mentioned previously for Ba IV (McMahon et al., 2007), but without any further consideration. By ignoring them, it is thus possible to interpret the measurements in terms of two independent interpenetrating H and G substructures, which are both periodic with common lattice parameters a and b but with different c: c_H ≠ c_G, the aperiodicity originating from the c_H/c_G ratio. Such typical non-modulated H-G structures have been reported for many elements, such as Sr V (McMahon et al., 2007), Rb IV (McMahon, Rekhi & Nelmes, 2001), K III (McMahon et al., 2006), tI19 Na (Lundegaard et al., 2009), Sb II, As III and Bi III (Degtyareva, McMahon & Nelmes, 2004a), and also Ba IVa (Nelmes et al., 1999; McMahon & Nelmes, 2004a). The observation of the above-mentioned reflections clearly points to modulations in any H-G structure. By improving the X-ray diffraction experiment, these reflections have been included in the refinement, and the structure models of Bi III (McMahon et al., 2007) and Sb II (McMahon et al., 2007; Schwarz et al., 2003) were re-interpreted in terms of modulated composites (COMP) with variation in the interatomic distances in both H and G and also between them. No attempt to apply an IM model has been done before for any H-G structure. In the present study, we show that, with the example of Ba IVb, this attempt not only makes sense, but it favours the IM model.

Similar to the reports on Bi III (McMahon et al., 2007) and Sb II (McMahon et al., 2007; Schwarz et al., 2003), we consider the strong hkl0 reflections as the main ones. However, all other reflections, i. e. hklm (m ≠ 0), are interpreted as satellites in our model. The difference concerns the hk0m (m ≠ 0) reflections, which are considered as main reflections for the G substructure in COMP. The reported scheme of the reflection distribution in Ba IVa (Nelmes et al., 1999) is very similar to that found here for Ba IVb. This is a strong hint to test the Ba IVa–Ba IVb transformation within the framework of an identical IM model, applying variation of the incommensurability vector q = βb* + γc*. It would be challenging to test the IM model for the other host–guest structures of the elements at different pressures, for instance the incommensurate-to-incommensurate phase transition in antimony (Degtyareva, McMahon & Nelmes, 2004b).

With improved diffraction measurements, the IM model gives the possibility of testing whether a similar or different density wave from Ba IVb is present in other H-G structures of the elements. Such a wave cannot be detected using a non-modulated composite model arising from an incomplete set of weak experimental reflections. The reason is that such a model a priori postulates the periodicity of the G atoms. However, atomic groupings, similar to the dumb-bells and triplets in Ba IVb, were found in the G chains of Bi III and Sb II using the weak hklm (l ≠ 0 and m ≠ 0) reflections for the COMP model (McMahon et al., 2007; Schwarz et al., 2003). It is not possible to predict which structure model, COMP or IM, is more relevant for the characterization of an H-G structure of an element at various pressures and temperatures. Only a complete structure refinement can show which model better fits the experimental diffraction intensities.

5. Conclusions

The interpretation of an intriguing high-pressure induced phenomenon is extremely sensitive to the structural model used. This is the so-called `one-dimensional chain melting', which has recently been reported for K (McBride et al., 2015) and Rb (McMahon & Nelmes, 2004a) H-G structures. The main experimental observation is a decrease and vanishing of intensity for hk0m reflections under certain pressure/temperature conditions (McBride et al., 2015; McMahon & Nelmes, 2004a). Assuming the composite structure models, this phenomenon is interpreted as the successive dis­appearance of interactions between H and G and even between G atoms, the so-called `melting' of G chains inside a crystal formed of H atoms (McBride et al., 2015; McMahon & Nelmes, 2004a). By assuming an IM structure model, this phenomenon can be interpreted as the disappearance of satellite reflections. The crystal structure becomes periodic if the intensity of the satellites is equal to zero. Unlike in the COMP models, this means that the structure recovers a new equilibrium, with periodic interactions in both H and G and between them. It thus appears that the conclusions are completely opposite to each other depending on the structure model. Hence, high-quality single-crystal data collection, accurate and detailed analysis of the diffraction data and reliable structure refinements are essential to improve our knowledge of the high-pressure H-G structures found for the elements.

Our results obtained for Ba IVb open some new perspectives for studying the complexity of the elements under high pressure.