If P has the form P = ±I₂, i.e., it describes the identity operation or a two-fold rotation, the lattice is only restricted by Equations (5)–(7), since every two-dimensional lattice is symmetric by these two operations. Thus, the valid lattices are represented by a three-dimensional subset of E³ (Figure 2a). This is the lattice restriction of layer groups in the oblique lattice system.

A matrix P representing a mirror operation fulfills: (9) det ( P ) = − 1and (10) tr ( P ) = p 11 + p 22 = 0

The lattice restriction induced by P corresponds to a plane in E³, which is described by an equation: (11) ( a i 2 , b i 2 , a i ⋅ b i ) V = 0with V ≠ o. V can be derived from P (see Appendix 1.1) by: (12) V = ( V x V y V z ) = ( p 12 − p 21 − 2 p 11 )

Since P is rational, so are the coefficients of V.

Two examples of this kind of restriction are depicted in Figure 2b: The horizontal plane represents the lattices fulfilling Equation (11) with V = (0, 0, 1)^T or a · b = 0 and the vertical plane V = (1, −1, 0)^T or a² = b². Lattices of the op and oc Bravais types of lattices (i.e., lattices of layers in both rectangular lattice systems) must fulfill these restrictions, respectively. Examples of non-crystallographic restrictions of this kind are given in Sections 2.12.1 and 2.12.2.

The set of solutions of Equation (11) contains ( a i 2, b i 2, a_i · b_i) triples of positive-definite G_i (i.e., the lattice restriction is valid), only if V fulfills: (13) V x V y < V z 2 4which is always the case for V of Equation (12), obtained from P fulfilling Equations (9) and (10). All V ≠ o representing parallel vectors (i.e., all λV, λ ≠ 0) describe the same lattice restriction. Notably, the equivalent lattice transformations represented by P and −P lead to the same lattice restriction (V and −V).

Since the matrix P representing a mirror operation must fulfill det(P) = −1 and tr(P) = 0, a lattice restriction of Equation (11) with given V is obtained from exactly two matrices P: (14) P = ± 1 l ( − V z 2 V x − V y V z 2 )where (15) l = V z 2 4 − V x V y > 0is a scale factor: l(V) = 1 for the form given in Equation (12) and l(λV) = |λ|l(V). V can be made unique by division by l and making V_x > 0. This form has the advantage that it can immediately be connected to the matrices ±P, which impose this restriction. Alternatively, the uniqueness of V can, for example, be achieved by making the elements integral, coprime and V_x > 0.

The matrix P representing a rotation by ψ ≠ 0, π has to fulfill: (16) det ( P ) = 1and (17) | p 11 + p 22 | < 2since p₁₁ + p₂₂ = tr(P) = 2cos ψ. The lattice restriction imposed by such a matrix corresponds to a line in E³, which is described by the equation: (18) U × ( a i 2 , b i 2 , a i ⋅ b i ) T = owith U ≠ o. Alternatively, the equation can be written as: (19) ( a i 2 , b i 2 , a i ⋅ b i ) = λ U Twith λ ∈ ℝ. U can be deduced from P (see Appendix 1.1) by: (20) U = ( U x U y U z ) = ( 2 p 21 − 2 p 12 − p 11 + p 22 )

Since P is rational, so are the coefficients of U. The lattice restriction resulting from the identity or two-fold rotation (three free parameters) can be considered as a special case of Equations (18) and (20), since the corresponding matrices P = ±I₂ lead to U = o, and as a consequence, Equation (18) is always fulfilled. Nevertheless, it seems more clear to treat the unrestricted case as a distinct case, and here, only U ≠ o are considered.

An example of this kind of restriction is given by the intersection of the horizontal and the vertical plane in Figure 2b: this line represents the lattices fulfilling a² = b² and a · b = 0 or U = (1, 1, 0)^T, corresponding to the metrics of lattices of the tp Bravais types of lattices (lattices of layers in the square lattice system) in the reduced setting. An actual example of a non-crystallographic lattice restriction of this kind will be detailed in Section 2.12.3.

The set of solutions of Equation (18) contains ( a i 2, b i 2, a_i · b_i) triples of positive-definite G_i (i.e., the lattice restriction is valid) only if: (21) U z 2 < U x U ywhich is always the case for U derived according to Equation (20) from matrices P fulfilling Equations (16) and (17). All U ≠ o representing parallel vectors (i.e., all λU, λ ≠ 0) describe the same lattice restriction. U can, for example, be made unique by making the elements integral and coprime and U_x positive. As opposed to the case of two free parameters, the lattice restrictions described byagiven U are derived from an infinity of matrices P. For example, the matrix representations: (22) P = ( 0 − 1 1 0 )and (23) P = ( 4 5 − 3 5 3 5 4 5 )of rotations by ψ = π 2 and ψ = tan − 1 ( 3 4 ), respectively, both lead to U = (1, 1, 0)^T (i.e., square lattices) (Figure 3).

The lattice restrictions read as: (27) ( a 2 , b 2 , a ⋅ b ) V k = 0with k = 1, 2. If the V_k represent parallel vectors (V₁ × V₂ = o), both restrictions are equivalent and, thus, identical to the resulting restriction. If V₁ × V₂ ≠ o, the number of free parameters is reduced to one. The possible lattices are described by Equation (18) with U = V₁ × V₂. An example is given in Figure 2b: the horizontal plane, described by V₁ = (0, 0, 1)^T, represents metrics of lattices in the op Bravais type of lattices and the vertical plane, described by V₂ = (1, −1, 0)^T, the metrics of lattices in the oc Bravais type of lattices. The intersection of these two planes is found by calculating U = V₁ × V₂ = (1, 1, 0)^T, which represents a line corresponding to the metrics of lattices in the tp Bravais type of lattices. Thus, if an OD structure is made up of orthorhombic primitive and orthorhombic c-centered layers and both layers possess the same (primitive) lattice, the lattices of both layers must be square.

Solutions with positive-definite G exist only for U fulfilling Equation (21). For example, a lattice cannot be restricted by a·b = 0 and a ⋅ b = 1 2 a ⋅ a represented by V₁ = (0, 0, 1)^T and V₂ = (1, 0, −2)^T, respectively, since the resulting restriction represented by U = V₁ × V₂ = (0, −1, 0)^T corresponds to the lattice restriction a² = a · b = 0, which is not the case for any two-dimensional lattice. An example of the combination of lattice restrictions resulting in non-crystallographic lattice restrictions is given in Section 2.12.4.

The lattice restrictions are given by: (28) ( a 2 , b 2 , a ⋅ b ) V 1 = 0and: (29) U 2 × ( a 2 , b 2 , a ⋅ b ) T = o

If V₁ and U₂ represent perpendicular vectors ( V 1 U 2 T = 0), the second restriction is a strict subset of the first and accordingly equivalent to the resulting restriction. If V 1 U 2 T ≠ 0, only the trivial solution a² = b² = a · b = 0, which does not describe a two-dimensional lattice, is common to both restrictions.

The lattice restrictions read as: (30) U k × ( a 2 , b 2 , a ⋅ b ) T = owith k = 1, 2. The restrictions are equivalent if the U_k are parallel (U₁ × U₂ = o) and, therefore, identical to the resulting restriction. If U₁ × U₂ ≠ o, only the trivial solution a² = b² = a · b = 0, which does not describe a two-dimensional lattice, is common to both restriction.

To express Equation (11) in terms of the lattice parameters, two cases have to be distinguished: V_z ≠ 0 (Table 5, Lines 2–5) and V_z = 0 (Table 5, Line 6). If V_z ≠ 0, Equation (11) can be written as: (31) a ⋅ b = − V x a 2 + V y b 2 V zwhich translates into: (32) γ = cos − 1 ( − V x a V z b − V y b V z a )

Concerning the restrictions of the relation between a and b, there are four subcases: If V_x = V_y = 0, then γ = π 2 and a > 0 and b > 0 are free. If V_x = 0, V_y ≠ 0, then a b > | V y V z |. If V_x ≠ 0, V_y = 0, then b a > | V x V z |. If V_xV_y ≠ 0, then: (33) b a ∈ ( | V z | − 2 l 2 | V y | , | V z | + 2 l 2 | V y | )where l is the scale factor defined in Equation (15).

If V_z = 0, Equation (11) can be written as: (34) b = − V y V x aand γ is free. This case corresponds to the lattice transformation where the mirror line is the bisector of a_i ∧ b_i. An example is the standard primitive setting of centered rectangular lattices where a = b [21].

Equation (18) can be written in terms of a, b and γ as: (35) b = U y U x aand (36) γ = cos − 1 ( U z U x U y a )

If the geometry of a lattice is restricted according to Equation (11), it can be unambiguously associated with two mirror operations represented by the matrix ±P′ according to Equation (14). The matrix representing a mirror operation is only unambiguously defined if the latter is one of these two operations, as derived in Appendix 1.4. Thus, only mirror operations at lines that are left invariant by the operations represented by ±P′ are unambiguously defined. The matrix representation P of a mirror operation at a line parallel to ua + vb is: (38) P = { P ′ if   P ′ ( u v ) = ( u v ) − P ′ if − P ′ ( u v ) = ( u v )

or dependent on the actual lattice metrics otherwise. The matrix representing a rotation by ψ ≠ 0, π is never unambiguously defined if there are two free lattice parameters.

The matrices representing mirror operations at a line parallel to ua + vb and normal to ua + vb and rotations by ψ are given in Table 6 and derived in Appendix 1.4.

If the lattice of a layer L_i is restricted according to Equation (11), the restriction can be associated with two mirror operations at perpendicular lines, represented by the matrices ±P of Equation (14). Thus, a description that suggests itself is in terms of rectangular centered lattices: since P is rational, both perpendicular mirror lines are parallel to an infinity of non-zero lattice vectors. The shortest of these two sets of vectors, a′_i and b′_i, span a rectangular lattice 𝔏′, which is invariant under the application of the mirror operations represented by ±P. As expected, also in this setting, there are two free lattice parameters, viz., a = |a′| and b′ = |b′|, whereas γ ′ = a ′ ^ b ′ = π 2 is fixed.

The coset decomposition of 𝔏′ in 𝔏_i furnishes the centering vectors of L_i. If the coset decompositions are {𝔏′} or { 𝔏 ′ , 1 2 ( a ′ i + b ′ i ) 𝔏 ′}, then 𝔏_i is a rectangular primitive or a rectangular c-centered lattice, respectively. In these two cases, the lattice 𝔏_j generated from 𝔏_i by the operation represented by P is identical to 𝔏_i. In all other cases, 𝔏_i ≠ 𝔏_j.

The intersection 𝔏_i ∩ 𝔏_j is invariant under the mirror operation described by P, and therefore, it is always either a rectangular primitive or a rectangular c-centered lattice: if u ∈ 𝔏_i ∩ 𝔏_j, then u ∈ 𝔏_j, and thus, it was generated from a vector u′ ∈ 𝔏_i. Since P² = I₂, the mirror image of u ∈ 𝔏_i is u′ ∈ 𝔏_j. Thus, u′ ∈ 𝔏_i ∩ 𝔏_j.

As has been shown in Section 2.4.3, a lattice restriction with one free parameter cannot be related to a unique transformation matrix P, and thus, the choice of a suitable basis is not as obvious as in the case of two free parameters. In OD families fulfilling VCβ, the sublattice common to all polytypes is an obvious choice. Otherwise, if square or hexagonal sublattices can be found, these would probably represent a good bases for centered lattices (the centering vectors are again determined by coset-decomposition).

For any lattice restricted according to Equation (18), a rectangular sublattice can be found: Since U_x, U_z ∈ ℚ, from Equation (18), it follows that the ratio of a_i · b_i to a i 2 is rational: (39) a i ⋅ b i = q a i 2 rwith q ∈ ℤ, r ∈ ℤ \ {0}. Thus, (a_i, qa_i − rb_i) spans a rectangular sublattice (which is not necessarily the largest rectangular sublattice of 𝔏_i). For example, a hexagonal lattice can always be represented by rectangular c-centered lattices with b = 3 a (or a = 3 b) (Figure 4). Nevertheless, as opposed to the case of two free parameters, this is not necessarily a convenient setting. Indeed, hexagonal lattices are usually described in the primitive setting, since it is more descriptive.

As has been stated in Section 2.3, if the layers of an OD family all feature the same lattice, the latter must be invariant under application of any σ-or λ-PO. Therefore, the OD family can be associated with one of the five two-dimensional Bravais types of lattices [16], and all σ- and λ-POs only appear in the directions of the crystallographic point groups (with the exception of cubic point groups, which are not possible for layers). The OD groupoid symbol contains the Hermann–Mauguin symbol of the layer group type of every kind of layer. The direction lacking translational symmetry is indicated by parentheses. The σ-POs are listed in curly braces below or besides the layer group symbols. The direction is implicitly derived from the place in the symbol. For tetragonal, trigonal and hexagonal OD families, five- and seven-placed symbols are used, since the σ-POs are not necessarily equivalent in all directions of {110} or {120}. If the translational components of the σ-POs are not indicated by intrinsic translations of screws or glides, they are specified additionally in brackets. The bracket-notation is likewise used for adjacent layers of different kind. Examples of OD groupoid family symbols composed of layers of one and two kinds are: (40) p 2 2 ( 4 ) 2 2 { n r − s , 2 n 2 , r + s ( 4 ¯ + 4 ¯ − n r + s , r − s ) n 2 , s n 2 , − r }and (41) p m m ( m ) p m m ( m ) [ r , s ]

Equation (40) describes an OD family made up of layers of one kind with tetragonal p(4)22 symmetry. The operations of the layer group and the σ-POs are given in the [100], [010], [001], [110] and [11̄0] directions. Thus, given a layer L_i, one possible orientation of the adjacent layer L_j is related to L_i by four-fold rotoinversions or by glides with planes parallel to either of the five given directions. Equation (41) describes an OD family made up of layers of two kinds, both with orthorhombic pmm(m) symmetry and the same lattice. The origins of the layer L_i and of one possible orientation of the adjacent layer L_j are connected by the vector ra_i + sb_i + c₀, where c₀ is a vector normal to the layer planes.

In OD families with partially overlapping layer lattices, σ-POs can appear in arbitrary (rational) directions. If they appear in non-crystallographic directions, the notation for OD families described above is not adequate. Therefore, it is proposed to list all symmetry elements in the same direction in columns with the direction given in the column head. The σ-POs are listed besides, not below, the layer group symbols, since the positions in the layer group symbol and the σ-PO list do not stand for the same direction. As an example consider the symbol of an OD groupoid family of non-polar layers: (42) p ( 4 ¯ ) 11 { [ 120 ] [ 2 1 ¯ 0 ] [ 1 3 ¯ 0 ] [ 310 ] 2 s 2 r n 2 , r 2 + s 2 n 2 , r 2 − s 2 }

Note that since the positions of the layer group symbol are not used for the σ-POs, the tetragonal layer group is indicated using the usual three-placed symbol. In this case, the σ-POs are listed only up to the lattice of the layer and not relative to the common sublattice of both adjacent layers to save space.

To indicate the relationship of the lattices of layers of different kinds, the base (a′, b′) of the layer is expressed in terms of the base (a, b) of a (arbitrarily chosen) global lattice either in the subscript of the Bravais symbol or in curly braces after the Bravais symbol. Thus, the layer group symbol may read as: (43) p { a ′ = a + b , b ′ = a − b } nm ( a )or (44) p a ′ = a + b , b ′ = a − b nm ( a )Finally, as has been stated in Section 2.8, the direction and rotation angle of a σ-PO does, in some cases, not fully describe the operation. It may, therefore, be necessary to indicate additional restrictions of the global lattice. If the global lattice is restricted according to Equation (11) (two free parameters), it is chosen to be rectangular, as described in Section 2.9. The rectangular lattice restriction is indicated by writing “op”—the symbol for the rectangular primitive Bravais type of lattices [21]—in front of the OD groupoid family symbol. If the global lattice is restricted according to Equation (18) (one free parameter), the restriction of the global lattice is written in front of the OD-family symbol in angle brackets. Depending on the case, this may be more favorably done in terms of vectors or lattice parameters: e.g., “〈a · b = − a 2 2, b² = a²〉” or “〈a = b, γ = 120^°〉”. The primitive settings of the square (〈a · b = 0, b² = a²〉) and hexagonal (〈a · b = − a 2 2, b² = a²〉) lattices may be abbreviated by the symbols tp and hp of the corresponding Bravais types of lattices [21]. An example where the specification of the lattice restriction and the indication of the location of the layer relative to the global lattice is necessary is given in Section 2.12.2.

In Figure 5, the lattice basis vectors of three times six different pairs of layers ( L i k, L j k), k = 1,..., 6, where the lattices of L i k and L j k are related by mirror operations, are represented. The mirror line is parallel to a_i (Figure 5a), normal to a_i (Figure 5b) or the bisector of a_i ∧ b_i (Figure 5c). In all three cases, there are two free parameters, and the lattice restriction can be written as in Equation (11) with V = (−1, 0, 2)^T (Figure 5a,b) and V = (1, −4, 0)^T (Figure 5c). Whereas the σ-POs in Figure 5a,b are different, the lattice transformations and, as a consequence, the lattice restrictions in both cases are equivalent, since mirroring at a line and at the perpendicular line are equivalent lattice transformations. In the examples of Figure 5a,b, if a_i is fixed, then the end point of b_i can be moved along a line normal to a_i. In Figure 5c, |b_i|/|a_i| is fixed and the angle γ_i = a_i ∧ b_i is free. In terms of the lattice parameters a, b, γ, the lattice restrictions read as b > a 2, γ = cos − 1 ( a 2 b ) (Figure 5a,b) and a = 2b (Figure 5c).

In Figure 6, two pairs of equivalent layers ( L i k, L j k), k = 1, 2 with symmetry p11(1) are schematized. In both cases, L i k and L j k are related by screws and rotations with axes parallel to [100] (expressed in the coordinate system of either layer or the common lattice of both layers) and intrinsic translation vectors n a i 5 with n = 0, 1, 2, 3, 4. Nevertheless, both figures represent different OD families. In Figure 6a, the linear part of the σ-POs expressed in the coordinate system of layer L_i is: (45) M = ( 1 2 5 0 0 1 ¯ 0 0 0 1 ¯ )whereas it is: (46) M = ( 1 4 5 0 0 1 ¯ 0 0 0 1 ¯ )in Figure 6b. Both cases can be distinguished by the restriction of the lattices. Since the lattices are related by a mirror operation, there are two free parameters and the lattices are restricted according to Equation (11) with V = (−1, 0, 5)^T (Figure 6a) and V = (−2, 0, 5)^T (Figure 6b). These restrictions expand to a i ⋅ b i = a i 2 5, and a i ⋅ b i = 2 a i 2 5, respectively. To describe the layer stacking according to the ad hoc notation of Section 2.10, the layers are expressed relative to global rectangular lattices (a_i, 5b_i − a_i) and (a_i, 5b_i − 2a_i), whose unit cells are indicated by dashed lines in Figure 6. Since the given layers are polar, a second layer contact is needed to fully describe an OD family. If the other sides of the layers contact via a glide with the plane parallel to the layer planes, the proposed OD groupoid family symbols read as: (47) O p b ′ = a 5 + b 5 1 1 ( 1 ) O p b ′ = 2 a 5 + b 5 1 1 ( 1 ) { 2 r ′ 2 2 5 + r ′ 2 4 5 + r ′ − ( − ) 2 6 5 + r ′ 2 8 5 + r ′ } and { 2 r ′ 2 2 5 + r ′ 2 4 5 + r ′ − ( − ) 2 6 5 + r ′ 2 8 5 + r ′ } { − − ( n r , s ) } { − − ( n r , s ) }with r′ = 0 in the example of Figure 6. Since the axes of the screws are parallel to the [100] direction, the directions of the POs can be given implicitly by the position in the symbol. If the rectangular sublattice is chosen as the setting of the layers, they possess non-Bravais centering with four centering vectors n 5 ( a + b ) and n 5 ( 2 a + b ) (n = 1, 2, 3, 4), respectively.

Partially overlapping layer lattices related by rotation are observed in KOH·2H₂O. The structure belongs to an OD family of non-polar layers of one kind. The layers possess orthorhombic symmetry pbm(a). Adjacent layers are related by four-fold screws with the axis parallel to the stacking direction [001] (Figure 7). Therefore, the lattices are restricted according to Equation (18), and there is only one free lattice parameter. In this case, U = (1, 4, 0)^T, or in terms of the lattice parameters: b = 2a, γ = π 2. The linear part of the 4 4 ̄ operation relating L_i and L_j reads as: (48) M = ( 0 2 0 1 ¯ 2 0 0 0 0 1 )

The square lattice (a, b) = (2a_i, b_i) is common to all layers (VCβ is fulfilled), and therefore, the structure is best described in terms of this lattice. The OD groupoid family symbol then reads as: (49) t p p a ′ = 2 a b m ( a ) { [ 2 1 ¯ 0 ] [ 210 ] [ 001 ] 2 r 2 3 4 + s 4 4 + 2 1 2 + r 2 5 4 + s 4 4 − n 2 , 1 2 − s n 2 , 7 4 + r 4 ¯ + n 2 , 1 − s n 2 , 1 4 + r 4 ¯ − }

Note that the directions of the σ-POs are given with respect to the layer lattices, not the common square sublattice. The intrinsic translations are given with respect to the primitive lattice vector in the given direction. For example, the intrinsic translations along [210] are given relative to 2a_i + b_i = a + b. In the actual structure, ( r , s ) = ( 1 2 , 1 4 ); thus, one possible orientation of the layer L_j is generated from L_i by a screw with intrinsic translation 1 2 ( a + b ) = ( a i + b i 2 ).

In Figure 8, three different OD families composed of an alternating stacking of non-polar layers of two kinds are depicted. All layers possess p2m(m) symmetry. The basis (a_j, b_j) of one possible orientation of layer L j k, k = 1, 2, 3 is related to the basis (a_i, b_i) of layer L i k by (a_j, b_j) = (a_i − b_i, a_i + b_i) (Figure 8a), (a_j, b_j) = (a_i−2b_i, 2a_i+b_i) (Figure 8b) and (a_j, b_j) = (a_i−b_i, 2a_i+b_i) (Figure 8c). Due to the orthorhombic layer group p2m(m), each layer lattice must be rectangular (a_i · b_i = a_j · b_j = 0). Moreover, according to the rules given in Section 2.6, the lattices must be square in Figure 8a,b (a_i = b_i, a_j = b_j, γ_i = γ_j = γ i = γ j = π 2) or fulfill b i = 2 a i, b j = 2 a j, γ i = γ j = π 2 in Figure 8c. Thus, the lattices are restricted according to Equation (18) with U = (1, 1, 0)^T (Figure 8a,b) and U = (1, 2, 0)^T (Figure 8c). Although, in all three cases, the layers L i k and L j k are restricted by the same lattice restrictions, the individual layers of each pair feature different lattice metrics. The lattice parameters are linked by a j = 2 a i (Figure 8a), a j = 5 a i (Figure 8b) and a j = 3 a i (Figure 8c). In the OD family depicted in Figure 8a, the lattice 𝔏_j is a common sublattice of all layers. Thus, the OD family fulfills VCβ. The point group of the family (the group generated by the linear parts of all POs [10]) is 422. In the examples in Figure 8b,c, on the other hand, polytypes with no translational symmetry exist; thus, only VCβ″ is fulfilled. The non-crystallographic point groups of both cases are written as ∞2 (The equivalence of such point groups is not obvious. Consider, for example, the point groups of rotations by ψ = q π / 2 and by ψ = q π / 3, q ∈ ℚ, which would both be written as ∞, but possess only one common element). The OD family symbols could be written according to the modifications of Section 2.10 as: (50) tp p 2 m ( m ) p a ′ = a + b , b ′ = a − b 2 / m 1 ( 1 ) [ r , s ]           ( Figure   8 a ) (51) tp p 2 m ( m ) p a ′ = 2 a + b , b ′ = a − 2 b 2 / m 1 ( 1 ) [ r , s ]           ( Figure   8 b ) (52) 〈 a ⋅ b = 0 , b 2 = 2 a 2 〉 p 2 m ( m ) p a ′ = 2 a + b , b ′ = a − 2 b 2 / m 1 ( 1 ) [ r , s ]       ( Figure   8 c )

The indication of the lattice restriction is redundant, since it can be deduced from the symmetry groups and the relations of the layers. Nevertheless, it is spelled out for clarity.

In Figure 9, the lattices of two equivalent layers L_i and L_j with c22(2) symmetry are represented by crosses and circles, respectively. The bases of the centered setting of the layers are (a_i, b_i) and (a_j, b_j) and the lattice parameters a, b and γ. The transformation matrix with respect to (a_i, b_i) reads as: (53) P = ( 1 7 12 ¯ 7 4 7 1 7 )

Substitution into Equation (20) and simplification by common factors leads to U = (1, 3, 0)^T or b = 3 a, γ = π 2. The transformation matrix with respect to the primitive basis ( a ′ i , b ′ i ) = 1 2 ( a − b , a + b ) of the L_i layer reads as: (54) P ′ = ( 3 7 8 ¯ 7 8 7 5 ¯ 7 )

Substitution into Equation (20) and simplification by common factors leads to U = (1, 1, −2)^T or in terms of the lattice parameters: b′ = a′, γ ′ = 2 π 3. Thus, the primitive settings of the L_i and L_j layers possess hexagonal metrics, and in this example, the expression of the symmetry operations may be more convenient in the primitive setting. Expression of centered layer groups in the primitive setting is in principle realized in the seven-placed OD groupoid symbols of hexagonal and trigonal OD families. The largest common lattice 𝔏_i ∩ 𝔏_j of the L_i and L_j layers is spanned by (a″, b″) = (3a′_i +2b′_i, −2a′_i + b′_i) and likewise possesses hexagonal metrics. This is indicated in Figure 9 by dashed lines. The matrices P and P represent a rotation by ψ = cos − 1 ( 1 7 ). Using the generalization of the printed symbols for screws [8], the adapted OD groupoid family symbol could be written as: (55) < b = 3 a , γ = π 2 > c 22 ( 2 ) { [ 001 ] [ 210 ] [ 3 2 ¯ 0 ] 2 π / cos − 1 ( 1 7 ) 2 π / cos − 1 ( 1 7 ) + 2 r 2 s 2 π / cos − 1 ( − 1 7 ) 2 π / cos − 1 ( − 1 7 ) − 2 r + 5 7 2 s + 12 7 }or, perhaps more concisely, using the seven-placed notation as: (56) h p p 211 ( 2 ) 211 { [ 001 ] [ 130 ] [ 510 ] 2 π / cos − 1 ( 1 7 ) 2 π / cos − 1 ( 1 7 ) + 2 r 2 s 2 π / cos − 1 ( − 1 7 ) 2 π / cos − 1 ( − 1 7 ) − }

Clearly, the usual notation for screws and rotations is cumbersome for non-crystallographic rotation angles, and further adaptations are needed. The non-crystallographic point group of the OD family is ∞2.