Group-theoretical analysis of 1:3 A-site-ordered perovskite formation

A group-theoretical analysis of 1:3 A-site-ordered perovskite structures is reported.

1:3 A-site-ordered perovskites were discovered in 1967 (Deschanvres et al., 1967). Interest in this class of materials increased sharply 33 years after the discovery in CaCu 3 Ti 4 O 12 of a giant low-frequency dielectric constant (" 0 ' 10 5 ), which is stable over a wide temperature range from 100 to 600 K (Subramanian et al., 2000;Homes et al., 2001). This discovery allowed CaCu 3 Ti 4 O 12 to be considered as a possible material for devices, in particular in elements of static and dynamic random access memory. The giant dielectric constant in CaCu 3 Ti 4 O 12 is usually associated with an extrinsic contribution, in particular with the internal barrier layer capacitance (Sinclair et al., 2002;Cohen et al., 2003;Tselev et al., 2004;Adams et al., 2006). This is due to the presence of a heterogeneous microstructure in the sample (semiconducting grains separated by insulating grain boundaries), which results in Maxwell-Wagner relaxation. Despite the extrinsic mechanism of the appearance of the giant dielectric constant in CaCu 3 Ti 4 O 12 , widely discussed in the literature, a number of works emphasize possible intrinsic contributions to the dielectric constant value (Liu et al., 2005;Zhu et al., 2007).
The discovery of the temperature-induced A-B intersite charge transfer effect, which is associated with large negative thermal expansion in LaCu 3 Fe 4 O 12 , aroused great interest (Long, Hayashi et al., 2009). Later, charge transfer between the different transition-metal cations at the square-planar A 0 and octahedral B sites was found in other 1:3 A-site-ordered perovskites: BiCu 3 Fe 4 O 12 Long, Saito et al., 2009), LaCu 3 Cr 4 O 12 and YCu 3 Cr 4 O 12 . The latter two compounds showed positive thermal expansion-like volume changes at the intersite charge transfer transition. These materials can be used in such applications as elasticity-tuned sensors and switching devices (Long, Hayashi et al., 2009). Note the site-selective electron doping effect, which is associated with a change in the valence in either the A 0 or the B sites, depending on the choice of the type of atom in the A site .
A wide variety of magnetic properties is also characteristic of 1:3 A-site-ordered perovskites which causes considerable scientific interest in these materials. For example, CaCu 3 -(Ge,Sn) 4 O 12 and (La,Dy)Cu 3 (Ge 3/4 Ga 1/4 ) 4 O 12 are ferromagnets (Shimakawa, 2008;Shiraki et al., 2007), CaMn 3 V 4 O 12 and YMn 3 Al 4 O 12 are antiferromagnets Toyoda et al., 2015), CaCu 3 Fe 4 O 12 , Ce 1/2 Cu 3 Ti 4 O 12 , BiCu 3 Mn 4 O 12 and CaCu 3 Fe 2 Re 2 O 12 are ferrimagnets Yamada et al., 2008;Saito et al., 2014;Takata et al., 2007), (Na,Ca,Y)Cu 3 V 4 O 12 are Pauli paramagnetics (Shimakawa, 2008;, and Ca(Mn x Cu 1Àx ) 3 V 4 O 12 and LuMn 3 V 4 O 12 are spin-glass phases Shimakawa et al., 2014). The magnetic properties of these materials can be tuned both by changing the chemical composition (Shimakawa, 2008) and by cation (or vacancy) ordering ). An unusual geometric frustrated state in the Fe 3+ spin sublattice was found in the A-and B-site-ordered quadruple perovskite CaCu 3 Fe 2 Sb 2 O 12 . The magnetic and transport properties of CaCu 3 Ru 4 O 12 have attracted attention due to their heavy Fermion-like behavior (Kobayashi et al., 2004). NaMn 3 Mn 4 O 12 shows a sequence of phase transitions associated with the spin, charge and orbital orderings (Prodi et al., 2004). Recently, a strong spindriven magnetoelectric effect was observed in a perovskite LaMn 3 Cr 4 O 12 with a centrosymmetric cubic structure (Wang et al., 2015). It is assumed that ferroelectricity in this compound is of an electronic nature and is formed due to magnetic ordering in two magnetic sublattices.
Thanks to all these physical properties, 1:3 A-site-ordered quadruple AA 0 3 B 4 X 12 perovskites are still of great interest. The diverse and unique physical properties of 1:3 A-siteordered perovskites are mainly due to the ordered structure of these crystals. We have previously carried out a study of cation-and anion-ordered low-symmetry modifications of the parent Pm " 3 3m perovskite structure Talanov et al., 2016). In this article, we emphasize the systematic study of perovskite-like structures with an order of 1:3 in the A sublattice which are formed as a result of real or hypothetical (virtual) structural phase transitions from the parent phase through various structural mechanisms.
Currently, there are two main theoretical approaches to the calculation of possible structures of the phases. The first approach is based on the International Tables for Crystallography (2010). We will call this the ITC approach for short. The ITC approach is described in detail by Bä rnighausen (1975,1980), Mü ller (2004Mü ller ( , 2013. The second approach is based on group-theoretical methods of the Landau theory of phase transitions (Landau, 1937). It is based on the theory of irreducible representations (irreps) of the space symmetry groups. We will call it the 'representation' approach, or the R-approach. Here we describe briefly each of these approaches.
The ITC approach accumulates crystallographic knowledge gained over more than 100 years -since the discovery of space symmetry groups by Fedorov (1891) and Schoenflies (1891). The visual representation of symmetry relations between different structures/phases is given in the form of a hierarchical 'family tree' or Bä rnighausen tree. The special Bä rnighausen formalism is proposed, including information about the paths of transition from the initial highsymmetry structures/phases (aristotype) with space group G to 'daughter' low-symmetry structures/phases (hettotypes) with space group H indicating the kind of maximum subgroup and index of the symmetry reduction. According to the Hermann theorem (Hermann, 1928) there are two kinds of maximal subgroups: isotranslational (now called 'translationengleiche', i.e. subgroups H have the same translation lattice as G) and isoclass (their name is 'klassengleiche', i.e. subgroups H having a different translation lattice, but belonging to the same crystal class as G). In the Bä rnighausen formalism these subgroups are denoted by 'tn' and 'kn', respectively, where n is an index of symmetry reduction (Mü ller, 2013). From the kinds of subgroups it is possible to deduce what and how many kinds of domains can result from a phase transition or topotactic reaction (Lotgering, 1959;Giovanoli & Leuenberger, 1969) involving a symmetry reduction. In addition, changes in the basis vectors, the origin shift and the splitting of Wyckoff positions are indicated. Numerous examples of the application of the ITC approach are given by Mü ller (2013) and Bä rnighausen (1980). This approach is a useful tool for solving the structure of new crystals as well as for the structural design of novel materials.
The R-approach has been widely used in the investigation of low-symmetry structures of crystals and structural mechanisms of phase transitions ever since the classical works of Landau and Lifshitz (Landau, 1937;Lifshitz, 1941;Landau & Lifshitz, 1976). It consists of two stages. The first stage includes finding all possible low-symmetry phases, corresponding order parameters (OPs), basic vectors of primitive cells and changing of primitive cell volume (V/V 0 ) for the irrep of the space group in the parent phase. At the second stage, the structures of the low-symmetry phases are determined. This problem was examined by Sakhnenko et al. (1986) and a general method for its solution was suggested there. The structure of the low-symmetry phase is connected with the socalled 'complete condensate of OPs' [the full set of the proper (primary) and the improper (secondary) OPs] as well as with the basis functions of irreps.
The group-theoretical analysis is quite a cumbersome procedure requiring the use of complex computer programs especially if OPs are multicomponent. There are some software applications for solution of the group-theoretical tasks: CONDENSATE and BASIS (Chechin, 1989), ISOTROPY (Howard & Stokes, 2005;Stokes & Hatch, 2002), the Bilbao Crystallographic Server (Aroyo et al., 2006;Perez-Mato et al., 2010) and others.
Visualization of the crystallographic analysis results of new structures is an attractive part of the ITC approach. This is used in the routine practice of solving structures. The R-approach is less visual, but it allows one to describe and predict not only atom but also spin and orbital structures, as well as predict important physical effects, revealing the physical nature of proper and improper OPs. This approach is naturally linked with phenomenological thermodynamics, quantum mechanics, optics, magnetism, orbital physics and other fields of science.
The use of only one of the above approaches (ITC or R) considerably reduces the possibilities of applying the obtained results to solving various theoretical and practical problems of crystallography and other sciences associated with it. These two approaches complement each other. In our study of 1:3 A-site-ordered perovskite-like structures, an emphasis will be placed on the R-approach. But in the final part of the article, the Bä rnighausen formalism will be used to visualize the genesis of 1:3 A-ordered perovskite-like structures and to establish the relationship between the ITC and R-approaches.
C. J. Howard and H. T. Stokes were the first to show that the 1:3 A-site ordering is associated with an OP, transforming by the irrep k 11 1 (M 1 + ) (Howard & Stokes, 2005). This study relies on the above work and supplements it. It will be shown that 1:3 A-site-ordered low-symmetry phases can be formed in different ways. A group-theoretical analysis of the structural mechanisms of formation of 1:3 A-site-ordered low-symmetry phases, as well as a group-theoretical map of their generation paths, are reported.
Thus, the aim of this study is a group-theoretical analysis of possible pathway formation and structural genesis of 1:3 A-site-ordered perovskites using the ITC and R-approaches.

Paths of 1:3 A-site-ordered perovskite formation
The space group of the ABX 3 cubic perovskite structure is Pm " 3 3m. In this structure, A cations occupy Wyckoff position 1a with cubo-octahedral coordination and with local symmetry m " 3 3m, octahedral B cations occupy Wyckoff position 1b with local symmetry m " 3 3m and X anions occupy Wyckoff position 3c with local symmetry 4/mm.m. Perovskites are referred to as anion-octahedral-type structures, i.e. BX 6 octahedra act as building blocks which are connected together by common vertices in three directions and are separated by A cations located in cubo-octahedral voids. Note that 1a and 1b positions in the perovskite structure are symmetrically equivalent. They are connected by an external automorphism, i.e. origin shift ( 1 2 1 2 1 2 ) of the unit cell. This means that the origin can be chosen both at A-(like in this work) and B-cation sites. The fact that the irreps responsible for these two descriptions are different must be taken into account.
The idealized perovskite structure is the archetype (this word originates from the ancient Greek one '"o' which means 'prototype') and/or aristotype (from the ancient Greek word 'o', 'highest') for low-symmetry modifications (Megaw, 1957(Megaw, , 1973Aleksandrov et al., 1981;Talanov et al., 2016). 1 Atom displacements (including ordered tilts or rotations of the BX 6 octahedra) and orderings, as well as their combinations, result in lower-symmetry superstructures.
In the Landau theory, the low-symmetry structure formation is described by proper and improper OPs, which are transformed according to the irrep of the space symmetry group of the high-symmetry parent phase. Irreps (according to which a proper OP is transformed) determine the symmetry and structural motif of low-symmetry phases near the transition point. However, when a low-symmetry structure is far from the temperature of the phase transition (T c ), the contribution of improper OPs to atom displacements (and/or orderings) can become essential (Dimmock, 1963;Bruce & Cowley, 1981;Sakhnenko et al., 1986;Molokeev & Misyul', 2012). The appearance of these contributions is connected with nonlinear interactions between different degrees of freedom in a crystal. There are two main notation schemes of irreps: by  In the first case, the designation is k n m , where n is the number of the wavevector k and m is the number of the corresponding irrep. In the second case, the wavevectors are denoted by different capital letters (À, M, X . . . ), and numbers of irreps are designated as subscript numbers and superscript signs '+' and 'À'. We will use the designations for irreps according to both said schemes. In addition, the OP direction in the OP space is necessary to indicate its unambiguous identification. The OPs transformed by irreps with different k values will be denoted by various Greek letters (, ', , É). In this article, we will consider only those irreps that satisfy the Lifshitz criterion (Landau & Lifshitz, 1976), i.e. they induce commensurate phases.
The full set of proper and improper OPs fully determines the structure and all possible symmetry-dependent properties of the crystal (Sakhnenko et al., 1986). The analysis of the full set of the OPs allows conclusions to be drawn about the nature of the crystal properties. The proper OPs that are responsible for the manifestation of ferroelectric properties, orderings and atom displacements, tilts of anion octahedra and Jahn-Teller distortions in perovskites are well known (Howard & Stokes, 1998Howard et al., 2003;Carpenter & Howard, 2009;Howard & Carpenter, 2010;Senn & Bristowe, 2018;. In Table 1, irreps according to which OPs are transformed inducing atom displacements 3 (polar and non-polar), atom orderings 4 and tilts of anion octahedra (or tilt-like distortions) in perovskites are summarized.
Let us return to the analysis of the ways of 1:3 A-ordered phase formation (Fig. 1). Irrep k 11 1 (M 1 + ) may in different ways enter into a full set of OPs, describing different mechanisms of 1:3 A-site-ordered phase formation. These OPs can be either proper or improper OPs. In addition, they can form combinations with other OPs. Thus, there are two types of mechanism of 1:3 A-site-ordered perovskite formation associated with proper and improper atom orderings. For both mechanisms, further analysis is connected with the number of proper OPs. For mechanisms of the first type, proper ordering in perovskite A sublattices and its combinations with other OPs are considered. For mechanisms of the second type, tilts of anion octahedra, atom ordering in the X sublattice, as well as combinations of these mechanisms with ordering in the B sublattice and atom displacements, are considered.
To enumerate all the low-symmetry phases formed as a result of atom displacements, it is necessary to use the OPs 382 Mikhail V. Talanov Table 1 Physical realization of the OP connected with atom non-polar and polar displacements, atom orderings and tilts of octahedra in perovskite structure (the unit irrep is not shown).
3 A set of space-group irreps of the parent cubic perovskite phase, basic functions of which make it possible to determine the atom displacements (including non-polar and polar displacements) at 1a, 1b and 3c Wyckoff positions of the Pm " 3 3m space group, is a mechanical (or atom-displacement) representation of the perovskite structure. that are transformed by the irreps taken from the composition of the mechanical (atom-displacement) representation of the perovskite structure. This representation includes 20 different irreps (Table 1), combinations of which induce more than 1200 low-symmetry phases. Because of the cumbersome nature of the complete list of all low-symmetry phases formed as a result of atom displacements, the study is limited to irrep k 12 10 (À 4 À ) only. This irrep is associated with the polar displacements of atoms. The research focuses on phases with polar displacements, because these phases possess ferroelectric properties.
An analysis of Table 1 showed that there is no irrep that is included simultaneously in the permutation representations on both the A and B sites in the perovskite structure. This means that there cannot exist a single OP that describes the formation of a perovskite-like structure with simultaneous Aand B-site ordering. For this reason, in Fig. 1 and in the present work, B-site ordering is considered only in combinations with other OPs, but not as 'one order parameter'.
Many phases with the same structures can be obtained by different paths (Fig. 1). For example, the structure of the rhombohedral phase with space group R " 3 3m and V/V 0 = 4 can be induced by the tilts of octahedra or by the combination of A-site ordering and X-site ordering or by the combination of A-site ordering and B-site ordering etc. This complicates the analysis of similar phases in Table 2, where the proper and improper OPs, the primitive cell translations and the changes in their volumes, as well as structural formulas are given.
Therefore, in what follows, only some (possibly minimal) sets of proper OPs from the full set of OPs will be given for these phases.
3. Structural mechanisms of 1:3 A-site-ordered perovskite formation 3.1. Proper ordering in the perovskite A sublattice 3.1.1. Case of one OP. There are no experimentally observed phase transitions from the parent phase with the cubic perovskite structure (archetype) to 1:3 A-site-ordered perovskite phases. Nevertheless, within the framework of the archetype concept, the genesis of various ordered phases from an archetype and the structural mechanism of their formation can be determined. Of course, such a structural mechanism is conditional. However, it plays a crucial role as it allows one to understand possible types of atom displacements and permutations that can cause the formation of the 1:3 A-siteordered perovskite phases from the archetype structure. Thus, by using the concept of structural mechanisms, the similarity, hierarchy and genesis of the studied crystal structures can be shown.
To list all possible low-symmetry phases with ordering in the A sublattice, obtained from the archetype with the space group Pm " 3 3m, we consider the corresponding permutation representation on the 1a Wyckoff position of the perovskite structure (Table 1) A classification of the OP combinations of 1:3 A-site-ordered perovskites that are considered in this work. The change in the primitive cell volume of the low-symmetry phase relative to the parent perovskite structure with the Pm " 3 3m space group is indicated in brackets after the designation of the space group.
The irreps describing the ordering of atoms in the 1a (and 1b) Wyckoff positions of the perovskite structure for the X, M and À points of the Brillouin zone are 3D, and for the R point the irrep is 1D. The irrep k 12 1 (À 1 + ) is the unit irrep and does not lead to the atom ordering.
It is known that four binary low-symmetry A-site-ordered perovskite phases with space groups Im " 3 3m (type of order is 1:3), Fm " 3 3m (type of order is 1:1) and two different phases with space groups P4/mmm (type of order is 1:1) are possible 384 Mikhail V. Talanov Table 2 Possible low-symmetry 1:3 A-site-ordered perovskite phases characterized by different types of OPs.
The following designations of OPs are used: k 10 (X) = , k 11 (M) = ', k 12 (À) = and k 13 (R) = É. In the second and third columns, the directions of OPs in OP space are given. Then notations of the irreps according to Kovalev (1993) are provided. The designations of the irreps by Miller & Love (1967) used in the ISOTROPY program are given in parentheses. The symbols V, O, P and D denote the physical nature of OPs associated with tilts of anion octahedra (or tilt-like distortions), atom orderings, and polar and non-polar atom displacements, respectively. The type of perovskite sublattice in which the OP is implemented is indicated by a subscript. The unit irrep k 12 ( 1 )(À 1 + ) is not shown. V/V 0 is the multiplication of the primitive cell volume as a result of virtual structural phase transition from the archetype structure. The superscript index in the structural formula means the type of Wyckoff position according to the International Tables for Crystallography.
3.1.2. Several OPs. (i) Combined proper atom ordering in A and B sublattices. The appearance of cation order in the A sublattice can be associated with cation ordering in the B sublattice. In this case, the transition to a low-symmetry structure is described by two independent OPs, which are transformed by the corresponding irreps entered into the permutation representation on the 1a and 1b Wyckoff positions of the perovskite structure. We obtained various lowsymmetry perovskite phases with simultaneous ordering in the A and B sublattices . We showed that there exist 121 phases with simultaneous cation ordering in the A and B sublattices, and only three structures with 1:3 order in the A sublattice: two R " 3 3m rhombohedral phases and one Pn " 3 3m cubic phase (Table 2). We consider in detail the structural mechanisms of Pn " 3 3m phase formation. This phase is an aristotype of a large family of quadruple perovskites which are sometimes referred to as 1322 perovskites . 5 This structure is generated by two proper OPs that are transformed by 4D reducible representation, formed as a direct sum of irreps k 11 1 (M 1 + ) and k 13 4 (R 2 À ). Irrep k 11 1 (M 1 + ) enters into permutation representation on the 1a Wyckoff position and also into mechanical representation on the 3c Wyckoff position of the perovskite structure. Irrep k 13 4 (R 2 À ) enters into permutation representation on the 1b Wyckoff position and also into mechanical representation on the 3c Wyckoff position. This means that lowsymmetry phase formation is accompanied by simultaneous A-cation and B-cation ordering and also by anion displacements. According to the grouptheoretical calculations the structural formula of the Pn " 3 3m ordered perovskite is as follows: 1/2 X 24k 3 . The structure of this phase is shown in Fig. 2(b). In this structure, the distorted octahedra with the B 4c and B 4b central atoms are located in a checkerboard order. A 2a and A 6d cations in a ratio of 1:3 are ordered in voids formed by octahedra. The structure is characterized by an eightfold increase in the volume of the primitive cell. This theoretically predicted structure was found in loparite (Na 0.59 Ce 0.41 ) 3 (Na 0.13 Ca 0.47 Ce 0.40 )Ti 2 (Ti 0.73 Nb 0.27 ) 2 O 12 (Zubkova et al., 2000). (ii) Combined proper atom ordering in the A sublattice and polar displacements. The combined OP, which transforms according to the direct sum of the irreps k 11 1 (M 1 + ) and k 12 10 (À 4 À ), generates only one 1:3 A-site-ordered phase with the space group R3m (more details in Section 3.2.2). The former irrep is responsible for the proper 1:3 A-site ordering, while the latter is responsible for the polar displacements. The structure of this phase is characterized by simultaneous atom ordering in all sublattices: 1:3 type of order in the A and B sublattices and 1:1:2 order type in the X sublattice. The ordering in the B and X sublattices is related to the improper OPs transformed by irrep k 11 7 (M 4 + ) and by the direct sum of irreps k 10 4 (X 3 À ), k 11 7 (M 4 + ), k 11 10 (M 5 À ), respectively. Anion octahedra in the structure of this phase are distorted (non-Glazer tilts) due to the contribution of the OP (' À' ' À' ' À') transformed by irrep k 11 9 (M 5 + ). The polarization vector in this phase is directed along the solid diagonal [111]. This phase is similar to the structure generated by the OP associated with the ordering in the X sublattice, but it is an improper ferroelectric, which is discussed in the next section.
3.2. Improper ordering in the A sublattice 3.2.1. One OP. (i) Ordering of atoms in the X sublattice. Atom ordering in the A sublattice can be a secondary effect of atom ordering in other perovskite sublattices. We have shown previously that the ordering in the B sublattice of the perovskite structure, described by a single OP, cannot lead to simultaneous ordering in the A sublattice ). Yet, the proposed ordering mechanism can be 386 Mikhail V. Talanov   realized with anion ordering in the X sublattice (Talanov et al., 2016). Of all the phases that are formed as a result of the anion ordering (induced by only one OP without the contribution of additional structural mechanisms), only three phases show 1:3 A-site ordering. These are rhombohedral phases with the space groups R3m, R3 and R32. These phases are generated by one 6D irrep k 11 10 (M 5 À ), but characterized by different directions in OP space: (' 1 ' 2 ' 1 ' 2 ' 1 ' 2 ), (' ' ' ' ' ') and (' À' ' À' ' À'). These phases have much in common: (a) They are characterized by 1:3 B-site ordering, which is generated by improper irrep k 11 7 (M 4 + ); this irrep enters into the permutation representations on the 1b and 3c Wyckoff positions of the perovskite structure [as well as in the mechanical representation on the 3c Wyckoff position (Table 1)].
(b) They are characterized by quadruplications of the primitive volume cells relative to the parent perovskite structure.
(c) In the structures of these phases, tilt-like distortions generated by an improper OP transformed by irrep k 11 9 (M 5 + ) are possible. In the case of the R3 phase the full set of the OPs also includes irreps k 11 5 (M 2 + ) and k 12 9 (À 4 + ) ( Table 1). (d) Irrep k 11 10 (M 5 À ) also enters into mechanical representations on the 1a and 1b Wyckoff positions that describe the displacement of the A and B cations.
In addition, it is important to note that phases with R3m and R3 space groups are improper ferroelectrics (the structures of similar phases, which are proper ferroelectrics induced by the same full set of the OPs, are described in Section 3.1.2). All three phases are improper ferroelastics.
Besides, another phase with the R32 space group and V/V 0 = 8 can be induced by two OPs transformed by the direct sum of irreps k 11 10 (M 5 À ) and k 10 4 (X 3 À ) (phase 4 of Table 2). The last irrep enters into the permutation representations on the 1b Wyckoff position. The structure of this phase can also be attributed to the structures formed as a result of combined Xand B-site ordering (Fig. 1).
(ii) Tilts of anion octahedra. The tilts of anion octahedra along with the atom displacements or orderings can also be OPs. Note that the tilts of anion octahedra are the most common type of distortions in perovskites (Megaw, 1957). Glazer and Alexandrov obtained 23 systems of possible tilts of anion octahedra in perovskites and proposed designations for their description (Glazer, 1972(Glazer, , 1975Aleksandrov, 1976). Based on the results of the group-theoretical analysis, it was found that the OPs associated with tilts of anion octahedra are transformed by two irreps: k 11 5 (M 2 + ), in-phase rotation, and k 13 8 (R 5 À ), out-of-phase rotation. These OPs, as well as their combinations, initiate the formation of 14 types of structures with Glazer tilts of octahedra (Howard & Stokes, 1998;Campbell et al., 2018).
In many studies, the superposition of the tilts of anion octahedra and other mechanisms of lattice distortions -atom displacements (Aleksandrov & Bartolomé, 2001;Aleksandrov, 1978 Woodward, 1997a), Jahn-Teller distortions (Balachandran & Rondinelli, 2013;Carpenter & Howard, 2009;Howard & Carpenter, 2010) -are considered. In the above works only 'simple' tilts of anion octahedra in-phase or out-of-phase were studied. However, as shown by Shirokov & Torgashev (2004), the tilts of anion octahedra in the perovskite structure can be induced not by two, but by six OPs, transforming according to the following irreps: k 10 2 ðX À 1 Þ þ k 10 10 ðX À 5 Þ þ k 11 5 ðM þ 2 Þ þ k 11 9 ðM þ 5 Þ þ k 12 9 ðÀ þ 4 Þ þ k 13 8 ðR À 5 Þ: The absolute majority of perovskite-like structures with tilts of anion octahedra induced by one of the two OPs [k 11 5 (M 2 + ) and k 13 8 (R 5 À )] or a combination of them can be described by the Glazer tilt system. As noted by Howard & Stokes (2005), distortions of structures generated by the 6D irreps k 10 10 (X 5 À ) and k 11 9 (M 5 + ) are not tilts of octahedra in Glazer approximations and, hence, cannot be described by the Glazer notation system. However, unconventional non-Glazer tilts are observed in hybrid organic-inorganic perovskites where additional degrees of freedom become possible (Duyker et al., 2016;Wu et al., 2018;Boströ m et al., 2018;Wei et al., 2018). That is why consideration of structures with non-Glazer tilts can be useful for describing possible types of distortions in a wide variety of compounds; therefore they are included in this section as 'tilt-like distortions'.
In order to solve the problem of enumerating all possible low-symmetry phases obtained from the parent phase of Pm " 3 3m by the tilts of anion octahedra, we consider a fourcomponent (24D) OP. This is transformed by the direct sum of the above irreps. This OP can generate the formation of 156 low-symmetry phases. However, only eight phases are characterized by 1:3 A-site ordering (Fig. 1), none of the phases being improper ferroelectrics.
The formation of one phase (Im " 3 3) induced by the OP, transforming according to the irrep k 11 5 (M 2 + ), is accompanied by in-phase tilts of octahedra (a + a + a + Glazer tilt system) ( Table 2). A phase with the Pn " 3 3n space group is induced by the OP, transforming according to the irrep k 10 2 (X 1 À ), which, in its turn, is associated with unconventional tilts of octahedra (Boströ m et al., 2018).
Each of the remaining six phases can be obtained as a result of a combination of different OPs: three phases induced by the OPs, transforming according to irrep k 10 10 (X 5 À ), and two phases induced by the OPs, transforming according to irrep k 11 9 (M 5 + ). The former are formed with an eightfold increase in primitive cell volume, and the latter with a fourfold increase. In these structures, there is an ordering in the B sublattice induced by improper OPs that are transformed by irreps k 10 4 (X 3 À ), k 11 7 (M 4 + ), k 13 4 (R 2 À ), which enter into the permutation representation of perovskite structure on the 1b Wyckoff positions (Talanov et al., 2016). The Pn " 3 3 phase can be induced by a combination of several OPs only (see the next section).
As a result of the in-phase tilts of anion octahedra with large inclination amplitude [in CaCu 3 Ti 4 O 12 the B-X-B bond angle is approximately equal to 140 (Bochu et al., 1979)], a square-planar environment of A 6b cations arises (Fig. 3b). Thus, 12 identical distances A-X (in the case of undistorted perovskite) are divided into four short, four medium and four long ones (Fig. 3c). This local configuration is stabilized by the Jahn-Teller effect in cases when the A 6b positions are occupied by Cu 2+ or Mn 3+ ions. Rare examples of Im " 3 3 structure formation are the compounds with a substitution (total or partial) of Jahn-Teller ions on the non-Jahn-Teller ones: Fe 2+ (Leinenweber et al., 1995), Li + (Mouron & Choisnet, 1987), Ti 4+ (Li et al., 2004;Avdeev & Nalbandyan, 2006), Co 2+ (Ovsyannikov, Zainulin et al., 2013), Pd 2+ (Shiro et al., 2013) and Pb 4+ (Sakai et al., 2017). In this case, a slight displacement of the A 6b atom in the direction perpendicular to the plane of square-planar oxygen coordination (Leinenweber et al., 1995;Ovsyannikov, Zainulin et al., 2013;Sakai et al., 2017) or splitting of A 6b positions Shimura et al., 2016) is possible.
Relatively large (Ca, Sr, Na, Pb, Bi) cations occupy the cubo-octahedral 12-coordinated A 2a positions. However, there are cases where smaller ions of transition metals Mn 2+ (Akizuki et al., 2013) and Cu 2+ (Akizuki et al., 2015) occupy these positions. In the CuCu 3 V 4 O 12 compound, there are significant temperature vibrations of Cu 2+ ions in oversized cubo-octahedral cages, which are interpreted as a rattling effect (Jeitschko & Braun, 1977). It is interesting to note the structural similarity of 1:3 A-site-ordered perovskites with the Im " 3 3 space group to the widely studied class of cage compounds filled skutterudites A 2a B 4 8c X 12 24g (A = rare-earth element, B = transition metal, X = pnicogen) with the same space group (Sales et al., 1996;Aleksandrov & Beznosikov, 2007). Atoms A rattle in the oversized X 12 icosahedral cage, reducing the lattice component of the thermal conductivity with a minor effect on the electronic properties (Sales et al., 1996;Nolas et al., 1999;Keppens et al., 1998). This feature allows filled skutterudites and other cage compounds to be considered as a promising class of thermoelectric materials.
From the crystal chemical point of view, the closest to the Im " 3 3 structure is the Im " 3 3m one (Table 2, Fig. 2a), which may be represented as an aristotype of the 1:3 A-site-ordered perovskites. The structure of the Im " 3 3 phase differs from the structure of the aristotype in anion positions: the anions in the structure of the Im " 3 3 phase occupy the two-parameter 24g Wyckoff position with m local symmetry, while in the Im " 3 3m structure the anions occupy the one-parameter 24h Wyckoff position with m2 local symmetry. Thus, the Im " 3 3 structure can be represented as the Im " 3 3m one with the in-phase tilts of anion octahedra characterized by the (' ' ') OP that is transformed in accordance with the irrep k 11 5 (M 2 + ).

Several OPs. (i) Combination of B-site ordering and tilts of anion octahedra.
To obtain the list of all possible 1:3 A-site-ordered phases resulting from the combination of B-site ordering and tilts of anion octahedra, it is necessary to consider the OP which is transformed according to the direct sum of irreps entered into the permutation representation of perovskite structure on the 1b Wyckoff position and in the enumeration (2). The permutation representation has the form (Table 1): This nine-component OP, transforming according to the direct sum of (2) and (3), generates 174 phases, with only six of them being characterized by 1:3 A-site ordering, B-site ordering and tilts of anion octahedra (Fig. 1) Table 2 (phases 7, 9 and 11). In the formation of phases 8 and 10, apart from the proper OP, improper OPs k 13 4 (R 2 À ) and k 10 4 (X 3 À ) participate. As a result, more complex 1:1:3:3 B-site ordering can be seen in these phases.
Let us consider in more detail the Pn " 3 3 phase formation mechanism (phase 12 of Table 2), since this phase is observed in a large number of quadruple perovskites, which are sometimes referred to as 1322 perovskites . This phase has a structure with eightfold primitive cell volume (Fig. 4). It is generated by a two-component OP, which is transformed by the direct sum of two irreps k 11 5 (M 2 + ) and k 13 4 (R 2 À ) [or k 11 5 (M 2 + ) and k 10 2 (X 1 À ) from the same full set of OPs], linked with the in-phase tilts of anion octahedra and 1:1 B-site ordering (rock-salt ordering type). 1:3 A-site ordering is generated by an improper OP k 11 1 (M 1 + ), which enters into the full set of OPs. This structure can be obtained in two ways from two different intermediate phases: from phase Im " 3 3 by 1:1 B-site ordering generated by the OP k 13 4 (R 2 À ) or from phase Pn " 3 3m by the tilts of anion octahedra induced by the OP k 11 5 (M 2 + ). In the known cases, structural phase transitions in the Pn " 3 3 phase pass through the first scenario and are accompanied by a charge disproportionation in the B sublattice (Yamada et al., 2008(Yamada et al., , 2016Meng et al., 2017).
The first synthesized compounds with simultaneous 1:3 ordering in the A sublattice and 1:1 rock-salt ordering in the B sublattice were CaCu 3 Ga 2 Sn 2 O 12 and CaCu 3 Ga 2 Ta 2 O 12 (Byeon et al., 2003). Later, a similar structure was discovered in CaCu 3 Cr 2 Sb 2 O 12 (Byeon et al., 2005), CaCu 3 Fe 2 Sb 2 O 12  and CaCu 3 Fe 2 Os 2 O 12 (Deng et al., 2016). The architecture of this structure allows the exchange interactions between Cu 2+ and the magnetic B cations to be influenced by introducing different cations in the B 0 sublattice. In addition, the nature of the magnetic properties depends on the degree of ordering in the B sublattice, which, as shown by the example CaCu 3 Fe 2 Nb 2 O 12 , varies with different synthesis conditions . The compound CaCu 3 -Fe 2 Re 2 O 12 is characterized by semi-metallic behavior with highly spin-polarized conduction electrons, a high Curie temperature and a significant magnetization, which are necessary for spintronic devices . Another unusual example of 1322 perovskites is CaCu 3 Fe 4 O 12 , a rare compound containing iron in higher oxidation states (Yamada et al., 2008). It demonstrates high catalytic activity and stability during oxygen evolution reaction (4OH À !O 2 + 2H 2 O + 4e À ) (Yagi et al., 2015).
The calculated structure of phase R " 3 3 (phase 9 of Table 2), which is observed in a rich group of ordered perovskites, is presented in Fig. 5(a). CaMn 7 O 12 (CaMn 3 Mn 4 O 12 ) (Bochu et al., 1980) is one of the compounds with such structure; it demonstrates a giant improper ferroelectricity as a result of the magnetic phase transition to an incommensurate helical magnetic structure below 90 K (Zhang et al., 2011a;Perks et al., 2012). In the phase with multiferroic properties, the direction of the electric polarization axes, the direction of the magnetic helices and MnO 6 rhombohedra twist coincide (Fig. 5b). According to Slawinski et al. (2009Slawinski et al. ( , 2010 in solid solutions CaCu x Mn 7Àx O 12 at x = 0 and 0.1, modulation of magnetic moments and also atom displacements below 250 K can be seen.
An unusual form of the mixed metal oxalate KLi 3 Fe(C 2 O 4 ) 3 presented as a perovskite-like structure with 1:3 ordering of both A and B sites was reported by Yao et al. (2017). In this structure, the Li and Fe atoms are characterized by an octahedral oxygen environment, and the K atoms occupy only one fourth of the A sites in the perovskite-like structure positions. Thus, the chemical formula of the compound in a perovskitelike form can be represented as K 1/4 & 3/4 (Li 3/4 Fe 1/4 )(C 1.5 O 3 ), where & is a vacancy. As noted by Yao et al. (2017), this structure is close to the calculated R " 3 3m structure generated by the combined atom ordering in A and B sublattices (phase 8 of Table 2). However, alternation of oxalate groups in the perovskite structure leads to distortion of anion octahedra and a symmetry change to the R " 3 3c space group (probably phase 11 of Table 2).
(ii) Combination of polar displacements and other mechanisms. In order to obtain a list of all possible 1:3 A-siteordered phases of proper ferroelectrics, it is necessary to choose an OP that transforms in the direct sum of the irrep k 12 10 (À 4 À ) connected with the polarization, and the irreps responsible for the realization of other physical mechanisms: orderings in A, B, X sublattices, and tilts of anion octahedra. All low-symmetry phases with 1:3 order in the A sublattice, obtained by the above ways, are given in Table 2 and Fig. 1.
There are 457 phases induced by the combinations of polarization and tilts and anion octahedra: 391 phases by polarization and X-site ordering, 24 phases by polarization and A-site ordering. But there are only three different 1:3 A-site-ordered polar phases among them. The common factor for all these ferroelectric phases is rhombohedral distortions of the crystal structures and 1:3 B-site ordering. The latter is related to the irrep k 11 7 (M 4 + ) entering into the full set of OPs for all phases given.
The phases with the R3m space group (phase 15 of Table 2) are generated by OPs that are transformed by the direct sum of two irreps, one of which is k 12 10 (À 4 À ) and the other k 11 1 (M 1 + ) or k 11 10 (M 5 À ) or k 11 7 (M 4 + ) or k 11 9 (M 5 + ). They originate from the combinations of polarization with: proper ordering in the A sublattice, ordering in the X sublattice, ordering in the B sublattice or the tilt-like distortion of the anion octahedra, respectively.
The phases with the space group R3 (phases 13 of Table 2) are generated by the OP which is transformed by the direct sum of two irreps: one of them is k 12 10 (À 4 À ) and the other is k 11 5 (M 2 + ) or k 11 9 (M 5 + ) or k 11 10 (M 5 À ) (Aleksandrov & Bartolomé, 2001;Stokes et al., 2002;Torgashev et al., 2005). They originate from the combinations of polarization with X-site ordering or one of the two variants of octahedral tiltlike distortions, respectively. The structure of this phase is formed by proper or improper tilts of anion octahedra with rhombohedral displacements of B atoms, co-directed with rotation axes (Stokes et al., 2002). The structure of this phase is observed in the quadruple perovskite Bi 1Àx/3 (Mn 3+ 3 )-(Mn 3+ 4Àx Mn 4+ x )O 12 in the range 0.10 < x < 0.27 (Mezzadri et al., 2011).
The phase with the R3c space group (phase 14 of Table 2) is generated by an OP that is transformed by the direct sum of two irreps k 12 10 (À 4 À ) and k 10 10 (X 5 À ). The full set of the OPs of this phase includes 19 irreps, which reflect the complexity of this structure.

Some particular cases of phase transitions in 1:3 ordered perovskites
In this section we will consider the mechanisms of formation of some experimentally observed phases, which were not included in the general classification. The reason for this is either at phase transitions the type of ordering in the A sublattice is more complicated than 1:3 (phases with space groups Pm " 3 3, Pmmm and I2/m), or the phase transition is associated with non-polar atom displacements (phases with space group I23).
3.3.1. Pm " 3 3 and Pmmm phase formation. Let us consider the Ce 1/2 Cu 3 Ti 4 O 12 compound. Depending on the synthesis conditions, this compound exists in two crystalline forms: with random and ordered Ce/vacancy distribution at the A site with Im " 3 3 and Pm " 3 3 space groups, respectively   (Fig. 6a). Ce/vacancy ordering leads to the appearance of L-type ferrimagnetism instead of antiferromagnetism in the disordered structure. Another compound with this structure is CuTa 2 O 6 (Propach, 1977), which can be 390 Mikhail V. Talanov   represented as a quadruple perovskite with a cationic deficit: &Cu 2 &Ta 4 O 12 .
The structural mechanisms responsible for the formation of an ordered modification with 1:1:3:3 order in the A sublattice differ greatly from those for the disordered phase (Section 3.2.1). The phase structure Pm " 3 3 is generated by an OP that is transformed by the direct sum of two irreps: k 11 5 (M 2 + ) and k 13 1 (R 1 + ). These irreps describe the tilts of anion octahedra (first irrep) and 1:1 A-site orderings (second irrep). The full set of the OPs also includes the irreps k 11 1 (M 1 + ) (1:3 A-site ordering), k 10 1 (X 1 + ) (A-site ordering), k 10 5 (X 2 + ), k 12 3 (À 2 + ) and k 13 3 (R 2 + ). The combinations of the irreps k 12 3 (À 2 + ) and k 10 5 (X 2 + ) [or k 10 1 (X 1 + )] from the full set of the OPs can act as the proper OPs. Note that the irrep k 10 1 (X 1 + ) is connected with the 1:1:3:3 A-site ordering if the direction of the OP vector in OP space is ( ) .
According to Ebbinghaus (2007), the structure of slow-cooled samples of the nonstoichiometric compound Cu 2+x Ta 4 O 12+ corresponds to the Pmmm space group with the splitting of the 1a Wyckoff position of the parent phase into eight single Wyckoff positions (only six of them are occupied by copper ions) (Fig. 6b). As in the case of the Pm " 3 3 phase, the structural phase transition to this phase can be described by an OP that is transformed by the direct sum of two irreps: k 11 5 (M 2 + ) and k 13 1 (R 1 + ). But in the case of the Pmmm phase, the OP (' 1 ' 2 ' 3 ), generated by the irreps k 11 5 (M 2 + ), corresponds to another system of tilts of anion octahedra: a + b + c + , but not a + a + a + (as in the case of the Pm " 3 3 phase) (Howard & Stokes, 1998). As noted by Ebbinghaus (2007), the site occupancy of the six different copper sites can vary significantly, depending on the content of copper (x) and the cooling speed (slow-cooling or quenching), giving rise to a cooperative vacancy ordering or to a statistical distribution.
3.3.2. I23 phase formation. The structure of LiCuNb 3 O 9 [the structural formula is (Li 8/3 Cu 8/3 ) 6b Nb 8c 8 O 24f 24 ] has the space group I23 (Sato & Hama, 1993). In addition, an analogous phase is observed in Fe 2+ -and Ni 2+ -modified CaCu 3 Ti 4 O 12 (Moriyama et al., 2013). According to Moriyama et al. (2013), ferroelectric properties are observed in these solid solutions. Concentration phase transition from the centrosymmetric Im " 3 3 phase into the non-centrosymmetric I23 phase is characterized by additional B-and X-atom displace-ments (Sato & Hama, 1993;Moriyama et al., 2013). There are three irreps k 10 1 (X 1 + ), k 10 9 (X 5 + ) and k 11 6 (M 2 À ) ( Table 1) that enter into mechanical representation on the 1b and 3c Wyckoff positions of the archetype perovskite structure, but they do not enter into mechanical representation on the 1a Wyckoff position (Table 1). However, only irrep k 11 6 (M 2 À ) associated with B-and X-site non-polar displacement and combined with irrep k 11 5 (M 2 + ) induces the phase with the I23 space group. Improper OPs enter into the full set of OPs; they are transformed according to the following irreps: k 12 2 (À 1 À ), k 12 3 (À 2 + ), k 12 4 (À 2 À ), k 11 1 (M 1 + ) (1:3 A-site ordering) and k 11 2 (M 1 À ). It is important to note that irrep k 12 10 (À 4 À ), according to which the ferroelectric OP (the polarization) is transformed, does not enter into a full set of the OPs. This means that the structural phase transition from Im " 3 3 to the I23 phase cannot be connected with the ferroelectric structural instabilities.
The phase transition into the polar Im phase is described by a full set of the OPs, which also include OPs transforming by   the irreps k 12 10 (À 4 À ), k 12 8 (À 5 À ), k 12 3 (À 2 + ), k 11 4 (M 3 À ), k 11 8 (M 4 À ) and k 11 10 (M 5 À ) (Fig. 8). The entry into the full set of the OPs of the irrep k 12 10 (À 4 À ) leads to the possibility of the appearance of ferroelectric properties in this phase. From the crystal chemical point of view, the stabilization of the polar phase is associated with the stereochemical effect induced by the presence of Bi 3+ ions with the 6s 2 one pair of electrons (Belik, Matsushita, Kumagai et al., 2017;Sławiń ski et al., 2017;Mezzadri et al., 2009).

Conclusions
Using group-theoretical methods of the phase transitions theory, possible 1:3 A-site-ordered structures are derived from more than 2600 low-symmetry perovskite-like phases obtained by different paths and then analyzed. These phases can be formed from a high-symmetry parent perovskite structure (archetype) as a result of real or virtual structural phase transitions connected with different OPs: atom orderings, atom displacements (polar and non-polar), tilts of octahedra and their combinations. From these phases all 1:3 A-site-ordered low-symmetry phases are identified and classified by irreps of the Pm " 3 3m space group (Fig. 1, Table 2). Proper and improper OPs, as well as theoretically calculated structures (space groups, multiplications of primitive cells, Wyckoff position splitting) are presented for each of these phases. The structural mechanisms of the formation of some experimentally known 1:3 A-site-ordered low-symmetry phases from an archetype perovskite phase have been studied in detail: CaCu 3 Ti 4 O 12 (the phase structure is characterized by the tilts of anion octahedra), CaCu 3 Ga 2 Sn 2 O 12 (the phase structure can be represented by a combination of the tilts of anion octahedra and 1:1 B-site ordering), CaMn 3 Mn 4 O 12 (the structure of the phase can be considered as a combination of the tilts of anion octahedra and 1:3 B-site ordering), Ce 1/2 -Cu 3 Ti 4 O 12 (the phase structure is characterized by a combination of tilts of anion octahedra and additional 1:1 A-site ordering) and others. Fig. 9 shows a modified Bä rnighausen tree of all possible 1:3 A-site-ordered low-symmetry phases, based on the ITC approach (ITC, 2010;Mü ller, 2013) with the irreps indicated, describing relative phase transitions. Note the fundamental peculiarity of convergence of two approaches in the modified Bä rnighausen tree. All group-subgroup relations when using the ITC approach are represented by different pairs of aristotype and hettotype phases.
In the case of the R-approach, irreps describe all the lowsymmetry phases that occur during a real or virtual phase transition from only one unchanged archetype phase, regardless of the intermediate phases. This is an important distinction. It significantly complicates the representation of the paths of formation of low-symmetry phases and the visualization of the results obtained. Therefore, the number of OPs describing the formation of some low-symmetry phases ( Fig. 9) is not the minimum number of OPs. For example, from the modified Bä rnighausen tree several OPs [k 11 1 (M 1 + ), k 11 7 (M 4 + ), k 13 8 (R 5 À ), k 10 2 (X 1 À ), k 11 9 (M 5 + )] can describe the formation of the phase with space group R " 3 3c (phase 11, Table 2) depending on the path. In the case of the R-approach, the same phase can be obtained from the structure of the archetype by only one of its proper OPs, which are transformed by irrep k 10 10 (X 5 À ). However, the combination of the two approaches allows us to track the formation of a full set of OPs, which is unchanged for each of the phases regardless of the path, and fully determines its structure.
Note that all the phases obtained using the R-approach are presented in Fig. 1 and Table 2, as well as Fig. 9. But in Fig. 9, there are several phases that were not obtained by using the R-approach. These are phases with space groups I " 4 43m, I432, Pm " 3 3n, P " 4 43n and P4 2 32. Let us explain this inconsistency in the results obtained by the R-and ITC approaches. The program COPL (Stokes & Hatch, 2002;Hatch & Stokes, 2002) helped us to ascertain that the first three phases are induced by OPs, which are transformed by irreps k 11 6 (M 2 À ), k 11 2 (M 1 À ) and k 10 5 (X 2 + ), respectively. Irrep k 11 6 (M 2 À ) enters into mechanical representation on Wyckoff positions 1b and 3c of the perovskite structure (Table 1). This irrep induces non-polar displacements of B and X atoms and, therefore, it has not been considered. Irreps k 11 2 (M 1 À ) and k 10 5 (X 2 + ) enter neither into permutational nor mechanical representations of the perovskite structure. According to Boströ m et al. The full set of OPs for the description of the Im " 3 3 ! I2/m ! Im!P1 phase transition cascade observed in BiMn 3 Mn 4 O 12 .
P " 4 43n and P4 2 32 can be induced by the combination of the OPs k 12 4 (À 2 À ) and k 10 5 (X 2 + ) in the first case, and k 11 2 (M 1 À ) and k 13 3 (R 2 + ) or k 12 2 (À 1 À ) and k 10 5 (X 2 + ) in the second case. The physical nature of these parameters is unknown. The 1:3 A-site ordering in all five cases is explained by the occurrence of the improper OP transformed by irrep k 11 1 (M 1 + ) in the full set of OPs. Thus, the five phases induced by the indicated irreps are beyond the limitations considered (Fig. 1). Besides, note the existence of two similar phases with the same space group R " 3 3c, but with the different splittings of Wyckoff positions. Atom Wyckoff positions from the A sublattice of the first phase correspond to atom Wyckoff positions from the B sublattice of the second phase and vice versa. This is due to the internal automorphism of the positions 1a and 1b in the perovskite structure. Thus, the structure of one of the phases is induced by the OP transformed by irrep k 13 9 (R 4 + ), which is equivalent to the irrep k 13 8 (R 5 À ) in the case when the origin is at the 1b position. But when the origin is at the 1a position, as in this work, the physical meaning of this OP is unclear, and that is why irrep k 13 9 (R 4 + ) has not been considered. Fundamentally important is the following result. Most of the hettotype phases presented here can be obtained in various ways from different aristotype phases (Fig. 9). For example, the phase with space group Pn " 3 3 (hettotype) can be obtained from the aristotype phases Pn " 3 3n, Pn " 3 3m or Im " 3 3 by t2, by t2 or by k2, respectively, which, in turn, can be obtained from the phase with the space group Im " 3 3m by k2, by k2 or by t2, respectively (Figs. 9, 10) Modified Bä rnighausen tree of all possible 1:3 A-site-ordered low-symmetry phases which was constructed using the ITC approach with the same limitations as in the R-approach (2a, 2b, 2c maximal primitive cell, only commensurate phases and 1:3 splitting type of 1a Wyckoff position of archetype structure). The irreps are designated in red. The numbers of phases from Table 2 are designated in green. All translations of the primitive cells of the lowsymmetry phases in this figure relate to the primitive cell of the aristotype phase, which may vary for different phases of the hettotypes. In Table 2, all translations are given relative to the primitive cell of a parent perovskite structure (archetype) that is common to all low-symmetry phases.
bility in the choice of the proper OPs within the unchanged full set of OPs is a new phenomenon revealed in our study. This extraordinary and important phenomenon requires further research. Thus, using the example of 1:3 A-site-ordered perovskites, this study showed that the combined use of ITC and R-approaches allows determination of OPs that describe the structural phase transitions (including virtual transitions) and the structures of low-symmetry phases as well as investigation of the structural genesis and group-subgroup relations between different crystalline phases/structures.