2.1. Synthesis

In our synthetic investigation of the Y–Zn system, elemental Y (Strem Chemicals, 99.9%) and Zn (Alfa Aesar, 99.9%) were used as starting materials. The elements were weighed out in the stoichiometric molar ratio of Y:Zn = 1:5 in an Ar-filled glove box, pressed into a pellet, and then placed into a fused silica tube, which was then evacuated and sealed. The sample was heated to 1100°C for 24 h to achieve a homogeneous melt, then annealed at 500°C for 168 h to allow for crystal growth, and finally cooled slowly to ambient temperature at a rate of 10°C h⁻¹.

2.2. Single crystal X-ray diffraction analysis

Single crystal X-ray diffraction data for YZn_5+x (x = 0.217) were collected on an Oxford Diffraction Xcalibur E diffractometer using graphite monochromated Mo Kα radiation (λ = 0.71073 Å) at ambient temperature. The collection and processing of the data set were performed using the CrysAlis Pro (v. 171.42.49; Rigaku Oxford Diffraction, 2022) software. The structure was solved with the charge flipping algorithm (Oszlányi & Sütő, 2004, 2005; Palatinus, 2004) using the program SUPERFLIP (Palatinus & Chapuis, 2007) and refined on F² using the program JANA2006 (Petříček et al., 2014). Further details regarding the refinements are given in Table 1 and the supporting information. The refined atomic coordinates and atomic displacement parameters for the basic structure are given in Tables 2 and 3, respectively.

Table 1 Crystallographic data for the modulated form YZn5+x Chemical formula YZn5.217 Wavelength dispersive X-ray spectroscopy composition YZn5.26 (3) a (Å), c (Å) 8.8811 (1), 9.2057(1) Volume (basic cell, Å3) 628.812 (12) Z 6 Modulation wavevector† q = a* + b* + 0.3041c* Superspace group‡ Crystal dimensions (mm) 0.193 × 0.137 × 0.092 Crystal color, habit Metallic gray, prismatic Data collection temperature Ambient Radiation source, λ (Å) Mo Kα sealed tube, 0.71073 Absorption correction Analytical Min, max transmission 0.024, 0.125 θmin, θmax 3.27, 27.87     Refinement method F2 No. of reflections 24910 No. of unique reflections [I > 3σ(I), all] 777, 1450 Rint [I > 3σ(I), all] 5.24, 5.55 No. of parameters, constraints 90, 0     Overall reflections   R[I > 3σ(I)], Rw[I > 3σ(I)] 2.72, 7.88 R(all), Rw(all) 5.60, 8.76 S[I > 3σ(I)], S(all) 1.94, 1.53     Main reflections   R[I > 3σ(I)], Rw[I > 3σ(I)] 1.76, 6.58 R(all), Rw(all) 1.90, 6.63     Satellite reflections   R[I > 3σ(I)], Rw[I > 3σ(I)] 11.12, 18.87 R(all), Rw(all) 24.85, 23.72 Δρmax, Δρmin(e Å−3) 4.73, −4.90 †Refined q vector without symmetry constraints: q = 0.3337(6) a* + 0.3314(6) b* + 0.3041(7) c*. ‡Symmetry operations: (x1, x2, x3, x4), (−x2, x1 − x2, x3, −x2 + x4), (−x1 + x2, −x1, x3, −x1 + x4), (−x2, −x1, −x3 + ½, −x4 + ½), (−x1 + x2, x2, −x3 + ½, x2 − x4 + ½), (x1, x1 − x2, −x3 + ½, x1 − x4 + ½), (x2, −x1 + x2, −x3, x2 − x4), (x1 − x2, x1, −x3, x1 − x4), (x2, x1, x3 + ½, x4 + ½), (x1 − x2, − x2, x3 + ½, −x2 + x4 + ½), (−x1, −x1 + x2, x3 + ½, −x1 + x4 + ½), (−x1, −x2, −x3, −x4)

Table 2 Refined atomic coordinates for the basic structure of YZn5+x Site Multiplicity x y z Uequiv Occupancy Y 6 0.61475 (10) 0.80738 (5) ¼ 0.0107 (3) 1 Zn1 6 0.86508 (10) 0.43254 (5) ¼ 0.0117 (3) 1 Zn2 4 0.51174 (10) 0.0122 (3) 1 Zn3 6 1 ½ ½ 0.0123 (6) 1 Zn4 12 0.8383 (2) 0.67858 (8) 0.41030 (6) 0.0139 (5) 1 Zn5 2 1 1 0 0.0196 (12) 0.988 (4) Zn6 2 1 1 ¼ 0.0140 (9) 0.664 (4)

2.3. Powder X-ray diffraction analysis

Phase analysis of the sample was performed using powder X-ray diffraction measurements. The sample was ground to a fine powder and placed on a zero-background plate. Diffraction intensities were measured on a Bruker D8 Advance Powder Diffractometer fitted with a LYNXEYE detector, using Cu Kα radiation (λ = 1.5418 Å) at ambient temperature. An exposure time of 1.0 s per 0.010° increment was used over the 2θ range 30–80°.

2.4. Wavelength-dispersive X-ray spectroscopy

To determine the elemental composition of YZn_5+x, wavelength dispersive X-ray spectroscopy (WDS) was performed on a sample whose powder X-ray diffraction pattern showed this to be the major phase. To prepare the sample for WDS measurements, a small amount of material was suspended in a conductive ep­oxy at one end of a short segment of an aluminium tube. Once the ep­oxy had hardened, the sample was ground down to produce a flat surface and then polished to reduce the number of surface scratches using a diamond lapping film (Precision Surface International Inc., 0.5 µm). Finally, the sample was carbon-coated. WDS measurements guided by back-scattered electron images were taken with a Cameca SX-Five FE-EMPA Microprobe, using Y₂O₃, elemental Zn, elemental Si, and ZnO as standards for the Y Lα, Zn Kα, Si Kα, and O Kα transitions, respectively.

3.1. Synthesis of incommensurately modulated YZn_5+x crystals

In our earlier investigation of the disordered YZn_5+x (x ≃ 0.2) structure, we uncovered channels of disordered Zn atoms running along the c axis, making this compound a member of the EuMg_5+x type (Fredrickson et al., 2022). We also noted, however, that a mechanism exists for the communication between the occupants of neighboring channels, opening a path to a potential ordered superstructure. Based on these interactions, we proposed a model for a superstructure. In our attempt to synthetically realize this superstructure, we carried out a modified version of our synthetic procedure. As before we pressed mixtures of the elements into pellets, brought them to a melt at 1100°C for 24 h and held them at 500°C for one week for crystal growth. This time, however, rather than quenching the samples in ice water, we introduced a controlled cooling step (10°C h⁻¹) to encourage superstructure formation. The reaction resulted in relatively large, well defined crystals, particularly in comparison to the quenched products from our previous syntheses containing the disordered YZn_5+x crystals. The crystals are metallic gray in color, with smooth surfaces, and are easy to grind into powders. In addition, the crystals exhibit high stability in air with no visible decomposition.

The powder X-ray diffraction data collected for a sample from which we picked the single crystal of YZn_5+x (x = 0.217) is presented in Fig. 2. All the major peaks are indexed to the YZn_5+x structure by reference to the single crystal data described below. Some minor peaks are assigned to a secondary phase, Y₂Zn₁₇, as well as others that appear to arise from an unknown, third phase. These results are consistent with metallographic analysis of a polished sample with back-scattered electron (BSE) imaging and WDS. BSE revealed two prominent phases in the sample: one appearing lighter, the other darker. The composition for the first of these was determined to be YZn_5.26 (3) from an average over 43 points, which corresponds closely with that expected for YZn_5+x. The second phase has the composition Y₂Zn_16.81 (8) (average over 30 points); this is assigned as the compound Y₂Zn₁₇. Needle-like domains of a third, minor phase with approximate composition YZn_2.2Si_0.6 were also occasionally observed, which apparently results from a reaction with SiO₂ from the fused silica ampoule. Altogether, though, the powder X-ray diffraction pattern and WDS analysis indicates the YZn_5+x is a major phase in the reaction product.

Figure 2 Powder X-ray diffraction pattern of the modulated form of YZn5+x (radiation: Cu Kα). Top: the experimental data plotted in a 2θ versus intensity form. Bottom: filmstrip style representation of the experimental data along with the simulated patterns for YZn5+x and Y2Zn17.

3.2. Analysis of diffraction pattern and symmetry

Crystals picked from these reaction products exhibit more complex diffraction patterns [Fig. 3(a)] than those obtained from quenching the samples from the annealing temperature. The strongest reflections can be indexed to a hexagonal cell, corresponding to the EuMg_5+x-type basic structure, with dimensions a = 8.8811 (1) Å and c = 9.2057 (1) Å. Additional weaker reflections are present in the spaces between these main peaks, as is evident in the reconstruction of the (hhl) layer of reciprocal space (Fig. 3). These new reflections correspond approximately to a supercell, but the distribution of their intensities is highly organized. They trace out rectangles, with the closest reciprocal lattice points of the basic cell being the systematically absent l = odd positions (e.g. hhl = 113, 223 etc.). A careful investigation for the positions of the superstructure reflections reveals that they are all separated from an absent main reflection by one of two vectors: q = a* + b* + 0.3041c* or q′ = −a*  − b* + 0.3041c*, as shown in Figs. 3(b) and 3(c), each of which creates a pattern with trigonal symmetry. No other reflections associated with a supercell are evident, suggesting that a superspace approach that considers the additional peaks to arise from modulations will be the most efficient route to solving the structure. In particular, a (3+1)D model (Smaalen, 2007) can be created when we assign q and q′ as belonging to separate twin domains, which are related by a sixfold rotation around c*, in-line with the hexagonal symmetry of the EuMg_5+x type basic structure. While there are several multiples of 60° that could be used to generate these twin domains, the threefold symmetry of the individuals will lead to only two symmetry-distinct crystal orientations.

Figure 3 Diffraction pattern of a YZn5+x (x = 0.217) crystal. (a) The satellite reflections exhibited along with the strong main reflections in the hhl plane. (b) Enlarged area, with the indices of the main reflections. (c) Indexation of the satellite reflections with the modulation wavevector (q = a* + b* + 0.3041c*) (red) and the corresponding vector for a twin domain (orange). Blue dotted circles denote absent main reflections.

In this approach, the experimental diffraction pattern is interpreted as the projection on 3D of a (3+1)D array of reflections, with the satellites having a component along the fourth dimension. The corresponding real space construction is a periodic structure in (3+1)D from which the physical incommensurately modulated structure is obtained by taking 3D cross-sections. The direction perpendicular to the physical cross-section is given by the a_s4 axis, which represents the superspace lattice vector for the modulation function, while the a_s1, a_s2 and a_s3 axes are counterparts to the physical a, b and c axes. They are, however, tilted out of the physical space axes in accordance with how much the phase of the modulation function changes for translations along the a, b and c repeat vectors of the basic cell.

A first step in building such a model is the assignment of the structure's (3+1)D superspace group. The q-vector q = a* + b* + 0.3041c* gives rise to a trigonal arrangement of satellite reflections, which is incompatible with the hexagonal space group P6₃/mmc of the EuMg_5+x type. In terms of potential trigonal subgroups of P6₃/mmc, we observe that the systematic absence condition associated with the c glide in P6₃/mmc, hhl: l = 2n_, still applies to the main reflections (Fig. 3), suggesting that the superspace group of the modulated structure is based on the P6₃/mmc subgroup . When we consider the full set of reflections, it is notable that the satellites only appear in the layer when l is odd, pointing to the condition hhlm: l+m = 2n. In terms of the symmetry operations of the (3+1)D superspace group, this corresponds to the c glide operation in 3D space being accompanied by a shift in the phase of the modulation (x₄) by ½. Altogether, these considerations indicate that the highest possible superspace group is P1c(σ₃)00s.

3.3. Structure solution and refinement

In the structure solution process, the charge flipping algorithm using the program Superflip converged on a (3+1)D electron density corresponding to the experimental diffraction intensities. The automated symmetry search and peak analysis of this electron density map agreed with the assignment of the superspace group as P1c(σ₃)00s, and yielded the basic framework of the EuMg_5+x-type basic structure. In addition, two atomic domains associated with the disordered channels in the EuMg_5+x type were identified, which we label Zn5 and Zn6.

The electron density features for the Zn5 and Zn6 sites show strong modulations with both occupational and positional components [Figs. 4(a) and 4(b)]. For the Zn5 site, the electron density contours in the x₃x₄ section trace out nearly linear domains centered at x₄ = 0.5 that are slanted to give a negative slope, and end on discontinuities near x₄ = 0.0 and 1.0. Similar features are found for the Zn6 site, except that its domain is centered at x₄ = 0.75, and its length along x₄ is shorter, with the width Δx₄ being about . To model the discontinuous nature of these domains, we used crenel functions (Petříček et al., 2016) centered at x₄ = 0.5 and x₄ = 0.75 for Zn5 and Zn6 respectively, with the corresponding Δx₄ values initially being set to 1.0 and , where the latter is a close rational approximant to ½ + ½σ₃ (the Δx₄ width for Zn6 needed to match the ends of the Zn5 and Zn6 domains in the physical cross-sections; see the supporting information). This is convenient as σ₃ varies from crystal to crystal (in the range of 0.304 to ∼0.331). In addition, first order positional modulations (based on Legendre polynomials tailored to the Δx₄ width of the domain) were applied to allow the atomic domains to slant in the x₃x₄ plane.

Figure 4 Contour maps of the Fourier electron density for (x3, x4) cross-sections through the Zn5 and Zn6 atomic domains. Top: the contours generated from the structure solution for the (a) Zn5 and (b) Zn6 sites show positionally modulated and discontinuous atomic domains. Bottom: the corresponding electron density maps for the refined model, in which atomic modulation functions with crenel functions are used for the (c) Zn5 and (d) Zn6 sites. The model positions for Zn5 and Zn6 are shown in gray and blue, respectively.

After setting these modulation functions for the Zn5 and Zn6 sites, in addition to first order harmonic positional waves on the remaining atoms, the refinement led quickly to a drop in the R factors for the satellite reflections. However, additional corrections were needed for a successful refinement. First, a twin component was included whose reciprocal lattice is rotated around the c axis by 60°, reflecting the hexagonal symmetry of the parent structure. Curiously, though, the twin-fraction invariably refined to approximately 0.75, regardless of which individual is integrated. As the diffraction patterns for the individuals overlap only on the main reflections, this suggested that the main reflections are systematically too strong relative to the satellites. Interpreting this as arising from disordered domains in the crystal, we used separate scale factors for the main and satellite reflections. Upon doing so, the twin fractions converged to 0.50, within two times the standard uncertainty, indicating that the crystal has balanced twinning.

In the final model, all the atoms are refined anisotropically, and first order modulations were applied to the harmonic atomic displacement parameters for all atoms but Zn6, with its relatively short and discontinuous domains. In addition, the Δx₄ widths for Zn5 and Zn6 were refined with the restraint that the edges of their atomic domains are aligned for clean transitions in the physical cross-sections, as in Δx₄[Zn6] = ½ + ½σ₃ + (1 − Δx₄[Zn5]), yielding values of 0.988 (3) and 0.664 (4), respectively. The refined model positions for the Zn5 and Zn6 sites are compared to the Fourier electron density contours in Figs. 4(c) and 4(d). In both cases, the model consists of slanted lines that align closely with the density features.

3.4. Structural interpretation of the modulated model

The nature of the modulation pattern is simple to interpret in terms of the disordered channels of the EuMg_5+x-type form of YZn_5+x described previously [Fig. 1(a)] and the (3+1)D Fourier electron densities for the corresponding atomic sites in the current structure. The Y and Zn1–Zn4 sites define the host structure of the EuMg_5+x type, and their electron density features are well described by harmonic functions with relatively small amplitudes (see Fig. S2 in the supporting information). By contrast, the Zn5 and Zn6 sites corresponding to the occupants of the channels have discontinuous atomic domains, indicating much stronger modulations. The Zn5/Zn6 sites can thus be seen as the major drivers of the modulation, with the positional displacements of the remaining atoms serving as adjustments to accommodate the resulting changes in their local environments.

The structural consequences of the Zn5/Zn6 site modulations become clearer when looking at a larger cross-section for the (x₃, x₄) plane containing them (Fig. 5). Zn5 and Zn6 domains alternate as we move from left to right on the physical axis, corresponding to the centers of the flattened octahedra and tricapped trigonal prisms whose alternation builds up the channel walls. While the Zn5 and Zn6 sites are made distinct by their association with these two different polyhedra, their domains show a high degree of correlation: their electron density features are both slanted from upper left to lower right, and following one domain down this slope brings one to right to the tip of the next atomic domain, on the other side of a small gap.

Figure 5 Connection between the (3+1)D Fourier electron density and structural features in physical space. (a) Fourier electron density contours corresponding to the Zn5 and Zn6 sites in an x3x4 section. (b) The corresponding modulated channel containing Zn5 and Zn6 atoms in physical space. (c) Modulated Zn5 and Zn6 sites in physical space laid over the Fourier electron density map of the xz plane of a 3D density constructed from the (3+1)D model (t-section). Such sections can appear somewhat messy due to the density features being broader than the model's atomic domains. The x4 offset of the cross-section off of the origin in (3+1)D space has been adjusted (t = 0.16) to reveal well separated density peaks along the channel. Vacant Zn6 positions are denoted by red dotted circles.

In fact, if one were to shrink these gaps, the Zn5 and Zn6 domains would coalesce into diagonal stripes that run with a slant relative to the a_s4 axis. Such a continuous slanted domain would encode a series of equally spaced Zn atoms whose spacing in physical space is mismatched with respect to the remainder of the structure (and determined by the angle of the slant). The high degree to which this pattern approximates a series of parallel diagonally oriented lines reveals that the Zn atoms in the channel have moved towards an equal spacing that is independent of the host lattice, as in a composite structure (Yamamoto, 1993; Rohrer et al., 2000; Sun et al., 2007). Indeed, the structure can be formally expressed as a composite structure in which the Zn6/Zn5 atoms occupying the channels are described as having their own lattice vector, c_guest, which is incommensurate to that of the host structure, c_host, with c_guest = c_host/(3 + σ₃). To perform refinements within this composite formalism, one first transforms the cell to a supercell (to obtain an axial q vector) and then assigns the reciprocal basis vectors of the guest composite part (the channel occupants) as c_guest* = 3c_host* + q_host and q_guest = 2c_host*. This corresponds to the following transformation matrix connecting the hklm indices of each reflection in terms of the host and guest composite parts:

When implemented, this provides the channel occupants with their own axis in the (3+1)D model. However, two crenel functions are still needed, representing different scenarios for the tricapped trigonal prismatic and flattened octahedral holes in the channels, and the overall R factors are quite similar to those obtained above.

While a composite model would normally suggest that all points along the host cell's channels can be populated by guest atoms, the gaps between the Zn5 and Zn6 domains suggest that certain positions are not suitable. In fact, the gaps correspond approximately in physical space to the centers of flattened Zn₃Y₃ octahedra that lie on opposite sides of the Zn6 sites. An explanation for these gaps can be discerned in the somewhat steeper slope of the Zn6 atomic domains than for the Zn5 atoms. The higher verticality here corresponds to a tighter localization around the average Zn6 position, indicating a preference for the center of the tricapped trigonal prism, where the Y–Zn contacts are shorter.

The features we have discussed so far explain the component of the modulation along the c axis of the EuMg_5+x type. The full q vector, q = a* + b* + 0.3041c*, also contains components along the perpendicular directions a* and b*, indicating that the occupation patterns of neighboring channels differ from each other. In the (3+1)D model, the channels are translationally related by steps of Δx₁ = ±1 and Δx₂ = ±1. In this construction, the non-zero components of σ₁ and σ₂ are reflected in the tilting of the a_s1 and a_s2 axes off the physical a and b axes, such that points along these axes are given by (x₁, 0, 0, +σ₁x₁ + t) and (0, x₂, 0, +σ₂x₂ + t), respectively, where t is the intercept with the a_s4 axis chosen when making the 3D physical cross-section (and is arbitrary in the case of an incommensurate structure). Since σ₁ and σ₂ are both equal to [as required by the superspace group ], moving from one channel to one of its neighbors along a_basic or b_basic results in a shift of the modulation phase by . These shifts are evident in the electron density maps for the 3D cross-section [t-maps, Fig. 5(c)], where the Zn6 vacancies in neighboring channels are offset from each other by steps of of the spacing between the vacancies along the channel.

This picture can be compared to the superstructure predicted previously from tracing paths of chemical pressure between channels through the tcp units. In this model, every third Zn6 site is vacant within each channel, creating a threefold superstructure along c. The occupation patterns of neighboring channels are connected through rhombohedral centering, with the primitive cell vectors being a_prim = a_basic + c_basic, b_prim = b_basic + c_basic, and c_prim = −a_basic − b_basic + c_basic. Transforming this arrangement to the hexagonal setting gives rise to the supercell. In Fig. 6, we plot the 3D structure of the incommensurately modulated form of YZn_5+x generated from our (3+1)D model. First in Fig. 6(a), we show a view down c, color-coding the different channels according to the relative heights of the channel occupation patterns. In this case, the a and b vectors of the supercell represent true crystallographic translations, labeled a_mod and b_mod, due to the commensurability of the modulation along these directions. This corresponds to the predicted pattern in the ab plane, as can be seen by comparison with Fig. 1(b).

Figure 6 Incommensurately modulated YZn5+x (x = 0.217) structure. (a) Overview of the structure viewed down [001]. (b) The modulated Zn channels with the one-third shift pattern (yellow, pink, and green). Vacant Zn6 positions are denoted by red dotted circles.

Next, in Fig. 6(b), we examine the occupation patterns of neighboring channels in more detail. In each channel, every third Zn6 atom is missing in this portion of the structure (red dotted circles), but as these positions are not translationally equivalent points in the basic structure (the EuMg_5+x-type unit cell has two Zn6 sites per cell along c) the overall pattern repeats every six Zn6 positions. The neighboring channels are shifted out of step by one Zn6 site, with the Zn6 coordination environments in the same orientation becoming shifted by of the approximate supercell vector along c. If the structure were to be commensurate, this would correspond in all respects to the predicted model.

The close approximation of σ₃ to raises the question of whether a commensurate model may be warranted. To answer this question, we attempted refinements in which σ₃ was set to and the structure was treated as commensurate in terms of the structure factor calculations. Regardless of which t₀ value was chosen, however, the R factors for the model were unreasonably high [overall R (I > 3σ) > 10.0 versus 2.7 for the incommensurately modulated model]. The incommensurability of the phase is further supported by the observation that the σ₃ value obtained from the diffraction patterns of different crystals can vary from 0.304 to 0.331 (in fact, some slight splitting of the satellites into closely spaced pairs of σ₃ values can be detected in the lattice reconstructions). As such, the spacing of Zn atoms along the structure's channels appears not to be locked into registry with the c parameter of the host structure.

How, then, does the incommensurately modulated structure differ from the idealized threefold superstructure along c? As we mentioned above, the σ₃ value in the (3+1)D model controls the average spacing of the Zn atoms occupying the channels, c_guest, relative to the c parameter of the host sublattice's average structure, c_host, as in c_guest = c_host/(3+σ₃). For σ₃ = , this gives rise to a commensurate arrangement with three c_host = ten c_guest, i.e. ten Zn5/Zn6 atoms in a threefold supercell of the disordered EuMg_5+x-type structure, matching that of the originally predicted superstructure with composition YZn_5.225. For lower σ₃ values, the average spacing of the channel atoms increases, leading to a lower overall Zn content of , e.g. YZn_5.217 for σ₃ = 0.3041, with each atom in the channel locking into a nearby Zn5 or Zn6 atomic domain.