2.1. Synthesis and crystallization

The preparation of MAPbI₃ single crystals has been reported elsewhere (Arakcheeva et al., 2016). Several crystals were initially tested for their crystal structure and crystal quality at ambient conditions. All of them showed the space group I422 crystal symmetry with the unit-cell parameters and the atomic coordinates identical to those reported by Arakcheeva et al. (2016). Preliminary diffraction measurements under high pressure showed as expected that the starting quality of the crystal (degree of mosaic and strains) has a significant effect on the high-pressure transformation (Fig. S1). Therefore, only the highest quality crystals have been selected for the final diffraction experiments.

2.2. Single-crystal synchrotron XRD experiments

Room-temperature (293 K) high-pressure (up to 20.27 GPa) XRD data were collected at the ID27 High Pressure Beamline of the European Synchrotron Radiation Facility (ESRF) in Grenoble. Diamond anvil cells were used with rhenium gaskets and Ne or Ar gases as the PTM to generate hydro­static conditions. The X-ray wavelength was set to 0.3738 Å. The minimal linear size of the crystals was about 10 µm. Diffraction data were recorded with a Mar165 CCD detector and the pressure was measured using the ruby fluorescence technique (Syassen, 2008). After decompression, additional measurements were conducted on the Ne-containing crystal to determine its structure under ambient conditions. CrysAlis PRO (Rigaku Oxford Diffraction, 2014) and JANA2006 (Petříček et al., 2014) software packages were used for data processing and structural refinement, respectively. Experimental details are listed in Tables S1 and S2 and are illustrated in Fig. 2 and also in Figs. S1, S2 and S3.

Figure 2 The XRD patterns illustrating the pressure-induced transformation of MAPbI3 with (a) Ne and (b) Ar as PTM. The powder XRD patterns calculated from the single-crystal experiments are presented at the logarithmic scale. Sections of the reciprocal space are shown for l = 0. The axes h, k (H, K) specific only for the tetragonal (pseudo-cubic) modification are emphasized in blue (red).

2.2.1. Structure determination

The general scheme of the structure determination is illustrated in Fig. 3 using the example of the crystal at ambient conditions and under 0.69 GPa up to 20.27 GPa pressures with Ne as the PTM. The starting (pristine) and the released (after exposure to the highest pressure) crystals are shown next to each other for comparison. The most probable symmetry of the structure at each pressure was determined by testing the inorganic framework for all possible space groups in all possible crystallographic systems (cubic, tetragonal, trigonal and ortho­rhombic). Next, after the refinement of the atomic positions of Pb and I [Fig. 3(a)], difference electron density maps were calculated for each case [Fig. 3(b)]. The pristine crystal can be characterized by the maxima in the expected MA positions [dark-blue circles in Fig. 3(b)]. These maxima are also perfectly identified at 0.69 GPa and for the released crystal, whereas they are absent at 20.27 GPa. However, even stronger and more localized maxima [cyan circles in Fig. 3(b)] are clearly visible for each pressure, with the exception of the starting (pristine) case. These additional maxima are attributed to Ne atoms, giving a compatible electron density contribution [Fig. 3(c)]. At 20.27 GPa, the usual MA positions show nearly zero electron density and only the Ne-attributed maxima are observable. We have to emphasize that these maxima could not be fitted with displaced MA cations. The schematic diagrams of the crystal structure for each pressure after including MA and/or Ne in the refined models are shown in Fig. 3(c). The residual electron density maps calculated after the refinements have values close to zero [Fig. 3(d)], this supports the models.

Figure 3 Determination of the MA and Ne positions in the crystal structure of MAPbI3 at selected pressures. Projections of the relevant fragments of the structure onto the ac plane are in (a) and (c). Small dots indicate I atoms in the plane for which the difference electron density maps are shown in (b) and (d) with positive (red) and negative (blue) areas. (b) The maps were calculated using only Pb and I atoms. The maxima of the difference electron densities are identified with MA cations (dark-blue circles) and Ne atoms (cyan circles). The density varies: from −0.32 to 1.58 e Å−3 for the released crystal at P = 1 atm; from 0.20 to 0.41 e Å−3 for the pristine crystal at P = 1 atm; from −1.44 to 1.97 e Å−3 for P = 0.69 GPa; from −1.13 to 1.86 e Å−3 for P = 20.27 GPa. (d) The residual electron density maps were calculated using all atoms of the structure. The residual electron density varies: from −0.3 to 0.51 e Å−3 atm for the released crystal at P = 1; from −0.27 to 0.23 e Å−3 for the pristine crystal at P = 1 atm; from −1.06 to 1.07 e Å−3 for P = 0.69 GPa; from −0.54 to 0.56 e Å−3 for P = 20.27 GPa.

Refinement of all atomic parameters for MA and Ne helped to confirm or correct the space group selected previously for the framework at each pressure. A similar procedure for the structure determination was used for all applied pressures for both Ne and Ar as the PTM.

As expected, the inclusion of Ne and Ar in the structure has a varying effect on the symmetry and the bulk modulus at different pressures. The resulting structures made it possible to determine the interatomic distances, and consequently the nature and hierarchy of interactions between various components of each structure.

The basic crystallographic information for eight different pressures with Ne as the PTM and six different pressures with Ar as the PTM is provided in Tables 1 and 2, respectively, and is visualized in Fig. 4. Further details are listed in Tables S1 and S2. It should be noted that, despite the reflections-to-parameters ratio which is 5.6 and 4.1 for the Ne-containing crystal at 16.43 and 20.27 GPa, respectively, the criteria R, wR, S = 0.051, 0.057, 1.44 for 16.43 GPa and 0.043, 0.064, 1.49 for 20.27 GPa, and the residual electron density ρ_max, ρ_min = 0.58, −0.60 e Å⁻³ for 16.43 GPa and 1.06, −1.25 e Å⁻³ for 20.27 GPa (column VI and VII in Table S1) show that the corresponding structure solutions are correct. These structures obtained at the highest pressures are essential for understanding the Ne intercalation, which is also confirmed by the presence of Ne in the released crystal under ambient conditions.

Table 1 Crystallographic data and composition for Ne-MAPbI3 in the 0–20 GPa pressure range   NexMAPbI3 NexMAPbI3 NexMAPbI3 Ne0.97MAPbI3 P (GPa) 0.69 → 1.5 → 2.69 4.56 → 7.4 16.43 → 20.27 1 atm (released) Crystal system Trigonal Orthorhombic Tetragonal Tetragonal Space group Im2m I4/mmm I422 a (Å) 17.3128 (9) → 17.0325 (9) → 16.7757 (9) 11.435 (3) → 11.196 (3) 10.700 (5) → 10.538 (5) 8.876 (1) b (Å) = a 11.437 (3) → 11.197 (3) = a = a c (Å) 10.6019 (5) → 10.4338 (5) → 10.2267 (5) 11.442 (3) → 11.201 (3) 10.620 (10) → 10.3793 (11) 12.672 (1) x in Nex 0.42 (1) → 0.60 (1) → 0.91 (1) 1.10 (1) → 1.41 (1) 2.17 (1) → 2.50 (1) 0.97

Table 2 Crystallographic data and composition for Ar-containing MAPbI3 in the 0–2.4 GPa pressure range   ArxMAPbI3 ArxMAPbI3 P (GPa) 0.18 → 0.49 → 0.98 1.34 → 2.10 → 2.39 Crystal system Tetragonal Orthorhombic Space group P42bc Immm a (Å) 8.850 (5) → 8.7468 (15) → 8.7222 (15) 12.1294 (12) → 12.0192 (10) →11.900 (11) b (Å) = a 12.1415 (12) → 12.0195 (10) → 11.990 (1) c (Å) 12.520 (5) → 12.398 (10) → 11.9979 (15) 12.1734 (15) → 12.0213 (10) → 11.920 (1) x in Arx 0.76 (1) → 1.00 (1) → 1.34 (1) 1.40 (1) → 1.78 (1) → 1.75 (1)

Figure 4 Evolution of crystallographic characteristics of MAPbI3 under pressure with (a) Ne and (b) Ar as the pressure transmitting media (PTM). Panels a(i) and b(i) show the symmetry transformation of the unit cell. Unit cells are shown in different colours for different crystallographic systems in relation to a primitive perovskite cube (green line). Panels a(ii), b(ii) show the pressure dependence of the unit-cell volume and crystal density. Points in the diagrams are coloured according to the unit cells in panels (i). Green and black points correspond to the pristine and released crystals, respectively.

3.1. The high-pressure NeMAPbI₃ compounds

The crystal structure at room temperature (293 K) was determined for 0.69, 1.5, 2.69, 4.56, 7.4, 16.43 and 20.27 GPa pressures and for ambient pressure after decompression (Table 1). Above 4 GPa an amorphous phase appears, coexisting with the crystalline one. The amorphous contribution slowly grows upon further increase of pressure and completely disappears after pressure is released (Fig. S1).

The XRD data obtained at 0.11 GPa indicate the coexistence of two phases: a tetragonal phase, characteristic of ambient pressure, and a pseudo-cubic phase, which is typical for higher pressures (Fig. S3). This is consistent with the first-order phase transition, which was reported before between 0.3 GPa and 0.4 GPa (Capitani et al., 2016; Szafrański & Katrusiak, 2016; Francisco-López et al., 2018). However, for the pseudo-cubic phase, we found the space group , which differs from the cubic and orthorhombic Imm2 reported previously by Szafrański & Katrusiak (2016) and Capitani et al. (2016), respectively. We observed a second phase transformation between 2.69 GPa and 4.56 GPa. It is also in good agreement with the literature value of 2.5 GPa (Szafrański & Katrusiak, 2016) and 2.7 GPa (Francisco-López et al., 2018). Even so, in contrast to the reported space group (Szafrański & Katrusiak, 2016), only its orthorhombic subgroup, Im2m, was found to describe the symmetry of the phase above 4.56 GPa. Furthermore, for the first time we observed a third transformation, from the orthorhombic to a tetragonal phase (space group I4/mmm) between 7.4 GPa and 16.43 GPa. The unit cells and space groups corresponding to each phase are shown in Fig. 4(a)(i). We explain the difference in the symmetry, the presence of a third phase transition and the lack of amorphization up to 20 GPa by the intercalation of Ne, which we found for the high-pressure phases.

Fig. 5 illustrates the evolution of the NeMAPbI₃ structure under compression.

Figure 5 Schematic diagram of the NeMAPbI3 structure evolution under compression and after pressure release. Panel (a) indicates the arrangement of Ne atoms at the faces of the primitive perovskite cubic unit cell. These faces are represented by cyan squares formed by I atoms. Depending on pressure, some of the Ne sites can be empty or partially occupied. Panel (b) shows a pressure-induced change of the crystal composition. In the chemical formula, y and(1 − y) refer to MA at the long-range-ordered and the non-localized (non-periodic) positions, respectively. Panel (c) presents the shortest interatomic distances for Ne–I, Ne–MA and I–MA under different pressures. Panel (d) demonstrates the main trend of the pressure-induced structure evolution, that is of a gradual increase in the number and occupancy of Ne sites, indicated in (a). Unexpectedly, all these sites are also partially occupied in the released crystal.

First, we observe evolution of the compound composition [Fig. 5(b)]: (i) a gradual pressure-induced growth in the Ne content and (ii) a gradual disappearance of the MA cation from the detectable, i.e. periodic over a long range, positions.

The observation (i) concerns positions of Ne atoms and their corresponding site occupancies. The intercalated Ne atoms are located in large voids of the inorganic framework, more precisely at the faces of the primitive perovskite cube [Fig. 5(a)], with a gradual increase in the occupancy of these sites upon compression [Fig. 5(d) and Figs. S4a and S5 in the supporting information]. The four neighbouring I atoms surround each Ne atom. The average occupancy of Ne sites starts at approximately one-third in the low-pressure phases and goes up with pressure, eventually approaching one when Ne atoms sit at each face. At 20.27 GPa, Ne sites are fully occupied for the faces of only four out of six possible orientations, and the remaining two are half occupied. One can therefore expect that even higher pressure is required in order to achieve the full occupancy. The corresponding composition, Ne₃PbI₃(MA), reflects the maximum possible Ne content in the structure.

The observation (ii) needs some extended explanation. A reversible transformation, which restores all the long-range-ordered positions of MA in the released crystal at ambient pressure (Fig. 3), indicates that this cation can be in two different states in the high-pressure crystal: the long-range-ordered state (i.e. periodic) and the randomly distributed one (i.e. non-periodic). In order to emphasize these two states of MA, we use the Ne_xMA_yPbI₃(MA)_1–y designation for the chemical formula, where indices y and (1 − y) denote the relative quantities of the long-range-ordered and the randomly distributed MA, respectively. The presence of two states for the MA cation is a direct confirmation of the assumption that the long-range ordering of MA is violated under high pressure, proposed by Ou et al. (2016), Capitani et al. (2016) and Szafrański & Katrusiak (2016). According to this assumption, a lack of long-range ordering of MA leads to destruction of the inorganic (Pb,I)-framework, which is kept by the I–MA periodic interactions. Indeed, a decrease in the amount for long-range-ordered MA leads to a huge increase in the atomic displacement parameters for I atoms (Fig. 6), which is a sign of the destruction of the inorganic framework. Destruction of the inorganic framework leads to compound amorphization. However, we observed that with the Ne PTM, the periodic crystal structure still exists up to 20 GPa. The reasons of this can be understood from the analysis of the Ne–I, Ne–AM and I–MA interatomic distances found for the long-range-ordered MA cation [Fig. 5(c)]. The short distances MA—Ne of ∼1.9 Å indicating the corresponding interaction at P < 3 GPa can be recognized as unstable with respect to pressure, since the content of the long-range-ordered MA rapidly reduces from 0.5 (4.56 GPa) to 0.25 (7.4 GPa) per chemical formula, and the long-range-ordered MA is no longer observed for P ≥ 16.3 GPa. If the expected rapid amorphization does not appear, it means that stabilization of the (Pb,I)-framework is kept by another stabilizer, which is different from MA; it is Ne atoms in the considered case. Indeed, for P > 4 GPa, the loss of the long-range order for more than 50% of MA switches the shortest interatomic distance (i.e. the strongest interaction of Ne) from Ne—MA to Ne—I [Fig. 5(c)]. Consequently, the Ne—I interactions can be considered as the cause of stabilization of the framework, preventing the amorphization.

Figure 6 Pressure-dependent atomic displacement parameters (ADP) of I atoms for the representative fragment of the inorganic framework. Panel (a) shows the fragment under three pressures with the long-range-ordered MA cation. Panel (b) shows the fragment under two pressures with the partially long-range ordered MA cation. Panel (c) presents the fragment corresponding to the absence of the long-range-ordered MA cation. The ADP ellipsoids are shown with 50% probability for each pressure.

The stabilizing role of Ne under high pressure is also confirmed by the distortions observed in the (Pb,I)-framework: the minimal distortions (the I—Pb—I angle ≃ 88.4–90.3° instead of the ideal 90° and the Pb—I—Pb angle ≃ 178–180° instead of the ideal 180°) were found in tetragonal structures at the highest pressure, when the long-range order MA is lost and the content of Ne is maximal (Table S3).

Thus, the progressive intercalation of Ne is the general trend in the pressure evolution of the NeMAPbI₃. The phenomenon is driven by the Ne—I interaction, which is substantially enhanced above 4 GPa.

Surprisingly, the occupation of Ne sites in all directions is preserved in the released structure under ambient pressure, but with a much smaller probability of approximately one-third [Fig. 5(d)]. The mean Ne–MA and Ne–I distances in the released structure, 2.83 Å and 2.78 Å, respectively, are very similar [Fig. 5(c)]. The minimum Ne–MA distance of approximately 2.3 Å in the released crystal can be responsible for this stabilization. However, this is the distance between the partially occupied Ne and MA sites, so it is problematic to say with certainty whether such separation is indeed realized.

In the 0–20 GPa pressure range the bulk modulus B₀, calculated using the Birch−Murnaghan model (Birch, 1947), varies from 5.3 GPa at the lowest to 10.6 GPa at the highest pressure. These numbers fall within the spread of values in the literature (Capitani et al., 2016; Jaffe et al., 2016) even for the crystalline phase at 20 GPa, which was absent for other PTMs.

3.2. The high-pressure ArMAPbI₃ compounds

The structure was determined at pressures of 0.18, 0.49, 0.98, 1.34, 2.1, and 2.39 GPa at room temperature (Table 2). Above 1.34 GPa an amorphous phase appears, coexisting with the crystalline one. The amorphous contribution grows rapidly with increasing pressure until no crystalline phase can be observed above 3.6 GPa (Fig. S2). This amorphization is irreversible in our experiments.

The tetragonal unit-cell parameters, characteristic for the ambient conditions, have been identified in the ArMAPbI₃ structure up to 1 GPa [Table 2 and Fig. 4(b)(i)]. The space group P4₂bc, which is new for the title compound, turned out to be the best fit in the 0.18–0.98 GPa pressure range. Only one transformation of this unit cell was detected for ArMAPbI₃, happening between 1 GPa and 1.3 GPa. The pseudo-cubic orthorhombic unit cell [Fig. 4(b)(i)] and the Immm space group are characteristic for the lattice for P > 1 GPa (Table 2). No distortion in the long-range order was detected for the MA cation. In comparison to NeMAPbI₃, growth in the Ar content as a function of pressure is 5.5 times larger, reaching the composition Ar_1.4MAPbI₃ at 1.34 GPa. In the case of Ne PTM, the nearly equivalent composition, Ne_1.41MA_0.25­PbI₃(MA)_0.75, occurs at 7.4 GPa (Tables 1 and 2). This indicates a much stronger interaction of MAPbI₃ with Ar than with Ne.

The pressure-induced structural evolution of ArMAPbI₃ (Fig. 7) is associated with a gradual growth in the Ar content [Fig. 7(b)], accompanied by the contraction of the Ar–I and Ar–MA distances [Fig. 7(c)]. For P < 1 GPa, the MA cations, Ar and I atoms closest to each other are arranged into chains, which polymerize in two dimensions upon further compression [Fig. 7(d)]. Influence of the lattice contraction on the chain geometry is illustrated in Fig. 8.

Figure 7 Sketch of the ArMAPbI3 structure evolution under compression. Panel (a) schematically shows a plane (pinkish grey square) where the Ar atoms are located. The plane is defined by I atoms and the centre of the MA cation. Panel (b) shows the pressure-induced change of the crystal composition. Panel (c) presents the shortest interatomic distances for Ar–I, Ar–MA and I–MA under different pressures. Panel (d) demonstrates the main trend of the pressure-induced structure evolution: below 1 GPa, Ar, MA and I atoms are arranged in chains, along the shortest Ar–I and Ar–MA distances, shown in (c); under increasing pressure, the number of the Ar positions rises, and the crossing chains form a layer. Each pinkish grey rectangle corresponds to the one shown in (a). Pinkish grey-coloured segments indicate the occupancies of the Ar sites.

Figure 8 Pressure-induced transformation of the tetragonal ArMAPbI3 phase. (a) Position of the I–Ar–MA–Ar– group within the (Pb,I)-framework. (b) Deformation of the group configuration and its connection to I atoms. Pink-coloured segments indicate the occupancies of the Ar sites. The MA–Ar and Ar–I interatomic distances are given in Å.

The shortest interatomic distances of ∼2 Å found for Ar–I and Ar–N (MA) at 2.1 and 2.39 GPa can be considered as a reasonable approximation if two arguments are taken into account. First, the value of 1.84 Å was theoretically predicted for the Ar–N separation for ambient pressure (Novak & Fortenberry, 2016). Second, large and prolate ADP ellipsoids of the I atoms imply an anharmonic character of the atomic displacements, which indicates that the actual Ar–I distances are longer.

Nevertheless, we consider the dramatic reduction of the minimum Ar–MA and Ar–I distances at P ≥ 2 GPa [circled by red line in Fig. 7(c)] as a trigger for the complete and irreversible structure amorphization. In fact, we recorded a crystalline state at the time of its destruction.

Thus, the pressure-induced formation of the stable I–Ar–MA–Ar– chains and their polymerization [Fig. 7(d)] is at the origin of the structural evolution and amorphization of ArMAPbI₃.

Detailed characteristics of the progressive changes in the ArMAPbI₃ structure under pressure are also given in the supporting information (Figs. S4b, S6 and S7).

3.3. Different impact of Ne and Ar as a pressure transmitting medium

The present results show that both Ne and Ar interact with MAPbI₃, but in different ways. Interactions between Ne and I atoms stabilize the inorganic (Pb,I)-framework up to 20 GPa and suppress amorphization of the crystal, despite the vanishing of the long-range ordering of MA. Ne serves as a structural stabilizer instead of MA for pressures higher than 4 GPa. Unlike Ne, Ar interacts with both I and MA even under low pressure of 0.18 GPa. These interactions accelerate the irreversible amorphization, which starts at P > 2 GPa. The difference between the influences of Ne and Ar is clearly related to the difference in their chemical activities, which are defined by their electronic configurations, i.e. their atomic radii being 0.38 Å for Ne and 0.71 Å for Ar.

The photo-luminescence (PL) microscopy images and steady-state PL spectra acquired under ambient pressure revealed that the PL properties were strongly dependent on the type of PTM and on the maximum pressure attained. Using the dual wavelength excitation technique (Mor et al., 2016) these observations, described in detail in Section S6, point to a markedly higher degree of amorphization for MAPbI₃ single crystals exposed to high pressure in Ar than in Ne. Thus, the optical characterization of MAPbI₃ supports the conclusions of the X-ray study that the large difference in the atomic radii of Ar and Ne leads to significantly different effects of high pressure on the crystallinity of MAPbI₃ after pressure release.

3.4. Influence of Ne and Ar on the methylammonium cation mobility

The role of the mobility of the MA cation is often discussed (Motta et al., 2015; Ou et al., 2016; Capitani et al., 2016; Szafrański & Katrusiak, 2016). The high-pressure amorphization is also directly linked to this phenomenon. According to Ou et al. (2016), Capitani et al. (2016) and Szafrański & Katrusiak (2016), the strong pressure-induced interaction between the MA cations and I atoms leads to the absence of the MA periodicity, which was considered as a template for the stability of the (Pb,I)-framework. Following this interpretation, our results support the following scenarios of the influence of Ne and Ar on the MA cation behaviour. In both cases, Ne–MA and Ar–MA interactions minimize the MA mobility by fixing the position of the MA dumbbell (the log-range-ordered form of MA). In particular, this explains the absence of cubic symmetry for the high-pressure phases.

In the case of Ne–PTM, up to ∼3 GPa, MA interacts with both Ne and I; that stabilizes its long-range ordering. For P > 3 GPa, intensifying interaction between MA and 12 neighbouring I atoms forces this cation to lose its long-range periodicity, first partially (for 3 GPa < P < 8 GPa) then completely (for P > 8 GPa). However, the Ne–I interaction becomes sufficiently strong to stabilize the (Pb,I)-framework. This prevents amorphization and maintains the crystalline state up to 20.27 GPa. These pressure-induced Ne–I interactions remain after decompression.

In the case of Ar PTM, MA cations interact with Ar to form –I–Ar–MA–Ar– chains as Ar enters the crystal. Formation of the chains prevents strong interaction between MA and I and, consequently, stabilizes the long-range periodicity of MA. At 1.34 GPa, some of the cations still exist outside of the chains. The uncovered cations stimulate additional absorption of Ar by the crystal, and all MA cations are involved in the polymerized chains at 2.39 GPa, but some of the Ar–MA and Ar–I distances are too short. On the one hand, it points to strong MA–Ar interactions, which benefit from the competition with the MA–I ones. On the other hand, the I–Ar–MA–Ar– chains get crowded in the restricted space between the PbI₆ octahedra and they crush the structure. This means collapse of the structure. Despite somewhat speculative character, this scenario can explain both the small observed contribution of the crystalline phase at 2.39 GPa and the rapid irreversible amorphization upon further pressure increase.