1. Chemical context

In this series of publications, we have structurally investigated several classes of amine complexes of gold(I) and gold(III) halides, whereby the term ‘amine' has been used loosely to include aza­aromatics. Background material is given in Parts 18 and (especially) 12 of this series (Döring & Jones, 2025, 2023).

In the series of 3,5-di­methyl­pyridine (3,5-lutidine, henceforth abbreviated to ‘3,5-Lut') complexes, we have previously determined the structures of (3,5-Lut)AuCl₃ and (3,5-Lut)AuBr₃, together with the 1:1 adduct of (3,5-Lut)AuBr₃ with (2-picoline)AuBr₃ (Döring & Jones, 2024a) and the ionic gold(I) derivatives [(3,5-Lut)₂Au][AuX₂] (X = Cl and Br; Döring & Jones, 2024b), which are isotypic. We have also presented the structures of three 3,5-lutidinium derivatives, namely (3,5-LutH)[AuBr₄] (the previous polymorph of 2), its diethyl ether solvate, and [(3,5-Lut)₂H][AuBr₄], in all of which the tetra­halogenidoaurate ions assembled to form approximately square networks with gold atoms at the corners and short bromine–bromine contacts Au—Br⋯Br—Au along the sides of the squares (Döring & Jones, 2016).

Here we present the structures of trans-di­bromido­bis­(3,5-lutidine)gold(III) tribromide, [(3,5-Lut)₂AuBr₂](Br₃) 1 (as two polymorphs 1a and 1b), a second polymorph of 3,5-lutidinium tetra­bromido­aurate(III), (3,5-LutH)[AuBr₄] 2, bis­(3-5-lutidinium) tetra­bromido­aurate(III) bromide, (3,5-LutH)₂[AuBr₄]Br 3 (as two polymorphs 3a and 3b), and tris­(3,5-lutidinium) bis­[tetra­bromido­aurate(III)] bromide, (3,5-LutH)₃[AuBr₄]₂Br 4. As established for the 4-methyl­piperidinium derivatives in Part 18 (Döring & Jones, 2025), the presence of both halide and tetra­halogenidoaurate ions in 3 and 4 extends the potential types of observed contacts and substructures.

2. Structural commentary

All compounds crystallize solvent-free. In the Figures (Figs. 1–6), the asymmetric units have been extended by symmetry where necessary to show complete residues; the dashed lines indicate short contacts, which are discussed in Supra­molecular features. Selected mol­ecular dimensions are shown in Tables 1–6.

Table 1 Selected geometric parameters (Å, °) for 1a Au1—N11 2.025 (2) N11—C12 1.340 (3) Au1—Br1 2.4174 (3) N11—C16 1.343 (3) Br2—Br3 2.5385 (3)             N11i—Au1—N11 180.0 Br1i—Au1—Br1 180.0 N11—Au1—Br1i 89.99 (6) Br3ii—Br2—Br3 180.0 N11—Au1—Br1 90.01 (6) C12—N11—C16 120.6 (2) Symmetry codes: (i) ; (ii) .

Table 2 Selected geometric parameters (Å, °) for 1b Au1—N11 2.020 (4) Br2—Br3 2.5388 (5) Au1—N21 2.032 (4) N11—C12 1.347 (5) Au1—Br1 2.4090 (4) N21—C22 1.346 (5)         N11—Au1—N21 180.0 Br3ii—Br2—Br3 179.55 (3) N11—Au1—Br1 89.753 (12) C12i—N11—C12 120.5 (5) N21—Au1—Br1 90.247 (12) C22i—N21—C22 121.5 (5) Br1i—Au1—Br1 179.51 (2)     Symmetry codes: (i) ; (ii) .

Table 4 Selected geometric parameters (Å, °) for 3a Au1—Br1 2.4197 (4) N11—C16 1.332 (5) Au1—Br2 2.4280 (4) N11—C12 1.334 (5)         Br1i—Au1—Br1 180.0 Br2—Au1—Br2i 180.0 Br1—Au1—Br2 89.450 (16) C16—N11—C12 123.0 (4) Br1—Au1—Br2i 90.550 (16)     Symmetry code: (i) .

Table 6 Selected geometric parameters (Å, °) for 4 Au1—Br2 2.4203 (5) Au3—Br7 2.4300 (5) Au1—Br3 2.4206 (6) N11—C12 1.321 (7) Au1—Br1 2.4255 (6) N11—C16 1.333 (7) Au1—Br4 2.4285 (5) N21—C26 1.333 (7) Au2—Br6 2.4159 (6) N21—C22 1.341 (7) Au2—Br5 2.4210 (5) N31—C36 1.334 (7) Au3—Br8 2.4174 (5) N31—C32 1.345 (7)         Br2—Au1—Br3 90.39 (2) Br5—Au2—Br5i 180.0 Br2—Au1—Br1 90.16 (2) Br8—Au3—Br8ii 180.0 Br3—Au1—Br1 179.13 (2) Br8—Au3—Br7ii 88.897 (18) Br2—Au1—Br4 178.57 (2) Br8—Au3—Br7 91.104 (18) Br3—Au1—Br4 89.93 (2) Br7ii—Au3—Br7 180.0 Br1—Au1—Br4 89.55 (2) C12—N11—C16 123.1 (5) Br6i—Au2—Br6 180.00 (3) C26—N21—C22 123.3 (5) Br6—Au2—Br5 89.722 (19) C36—N31—C32 123.8 (5) Br6—Au2—Br5i 90.279 (19)     Symmetry codes: (i) ; (ii) .

Figure 1 The formula unit of compound 1, polymorph 1a, in the crystal. Ellipsoids are drawn at the 50% probability level.

Figure 2 The formula unit of compound 1, polymorph 1b, in the crystal. Ellipsoids are drawn at the 50% probability level.

Figure 3 The formula unit of compound 2 in the crystal. Ellipsoids are drawn at the 50% probability level.

Figure 4 The formula unit of compound 3, polymorph 3a, in the crystal. Ellipsoids are drawn at the 50% probability level.

Figure 5 The asymmetric unit of compound 3, polymorph 3b, in the crystal. Ellipsoids are drawn at the 50% probability level.

Figure 6 The formula unit of compound 4 in the crystal (extended by symmetry to show complete residues). Ellipsoids are drawn at the 50% probability level.

Compound 1, polymorph 1a, crystallizes in P with Z = 1. The gold atom and the central bromine of the tribromide ion lie on inversion centres. Polymorph 1b crystallizes in C222₁ with Z = 4. The gold atom, the nitro­gen atoms and the ring atoms at the 4-position of the lutidine ligands, and the central bromine of the tribromide ion all lie on twofold axes. Compound 2 crystallizes in P3₂ with Z = 3. Compound 3, polymorph 3a, crystallizes in C2/c with Z = 4. The gold atom lies on an inversion centre and the bromide ion on a twofold axis. Polymorph 3b crystallizes in P2₁/c with Z = 8 (Z′ = 2) and all atoms on general positions. Compound 4 crystallizes in P with Z = 2. One gold atom lies on a general position and two on inversion centres.

The tetra­bromido­aurate(III) ions show the expected square-planar (4/mmm) symmetry to a good approximation, although there is some scatter of the Au—Br bond lengths, which range from 2.4046 (8) to 2.4300 (5) Å. The cis angles at gold are all within 1.1° of the ideal 90°, and the maximum deviation for the trans angles is 2.4°. The C—N—C angles of the lutidinium cations lie in the narrow range 123–124°.

The formula units of the polymorphs 1a and 1b are closely similar, despite the difference in formal symmetry. The Au—N bonds are short, as is usual for mutually trans Au—N bonds at Au^III centres. The C—N—C angles of the lutidine ligands are 120.6 (2)° for 1a and 120.5 (5), 121.5 (5)° for 1b. The angle between the lutidine ring planes is 0° for 1a (by symmetry) and 5.1 (4)° for 1b. Even the relative orientations of the cation and the anion are similar, with N—Au⋯Br—Br torsion angles of −129.79 (2) and 50.21 (2)° for 1a and −120.71 (6) and 59.29 (6) for 1b (see also Supra­molecular features).

3. Supra­molecular features

In the packing diagrams, atom labels indicate atoms of the asymmetric unit; hydrogen atoms of the ring CH groups are generally omitted unless relevant to the packing. We subjectively assess the C—H⋯Br contacts to be less important than N—H⋯Br. In the text, primes (′) indicate previously defined or generalized symmetry operators. Hydrogen bonds are listed in Tables 7–12.

Table 7 Hydrogen-bond geometry (Å, °) for 1a D—H⋯A D—H H⋯A D⋯A D—H⋯A C14—H14⋯Br1iii 0.95 2.95 3.762 (3) 144 C12—H12⋯Br2 0.95 2.76 3.683 (3) 165 C12—H12⋯Br3 0.95 3.05 3.718 (3) 129 C16—H16⋯Br3i 0.95 3.00 3.689 (3) 130 C17—H17C⋯Br3iii 0.98 3.04 3.946 (3) 155 Symmetry codes: (i) ; (iii) .

Table 8 Hydrogen-bond geometry (Å, °) for 1b D—H⋯A D—H H⋯A D⋯A D—H⋯A C15—H15A⋯Br1iii 0.98 3.01 3.500 (5) 112 C22—H22⋯Br1i 0.95 3.05 3.367 (4) 102 C22—H22⋯Br2iv 0.95 2.88 3.780 (4) 159 C12—H12⋯Br3i 0.95 2.90 3.662 (4) 138 C14—H14⋯Br3v 0.95 3.04 3.802 (4) 138 C14—H14⋯Br3vi 0.95 3.04 3.802 (4) 138 C24—H24⋯Br3vii 0.95 2.96 3.708 (4) 137 C24—H24⋯Br3viii 0.95 2.96 3.708 (4) 137 Symmetry codes: (i) ; (iii) ; (iv) ; (v) ; (vi) ; (vii) ; (viii) .

Table 9 Hydrogen-bond geometry (Å, °) for 2 D—H⋯A D—H H⋯A D⋯A D—H⋯A N11—H01⋯Br1 0.86 (7) 2.96 (8) 3.471 (8) 120 (6) N11—H01⋯Br1i 0.86 (7) 2.83 (8) 3.612 (8) 153 (7) C16—H16⋯Br2ii 0.95 2.96 3.699 (9) 136 C17—H17A⋯Br2iii 0.98 2.99 3.881 (9) 152 C18—H18C⋯Br2iv 0.98 2.99 3.948 (9) 165 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) .

Table 10 Hydrogen-bond geometry (Å, °) for 3a D—H⋯A D—H H⋯A D⋯A D—H⋯A N11—H01⋯Br3 0.87 (4) 2.42 (4) 3.234 (4) 158 (4) N11—H01⋯Br3ii 0.87 (4) 2.42 (4) 3.234 (4) 158 (4) C18—H18A⋯Br1i 0.98 2.93 3.862 (4) 159 C16—H16⋯Br2 0.95 3.00 3.704 (4) 132 C16—H16⋯Br1i 0.95 3.04 3.908 (4) 153 Symmetry codes: (i) ; (ii) .

Table 11 Hydrogen-bond geometry (Å, °) for 3b D—H⋯A D—H H⋯A D⋯A D—H⋯A N11—H01⋯Br10 0.77 (4) 2.49 (5) 3.215 (7) 157 (8) N21—H02⋯Br9 0.78 (4) 2.46 (4) 3.220 (7) 168 (8) N31—H03⋯Br9 0.77 (4) 2.47 (5) 3.203 (6) 159 (7) N41—H04⋯Br10 0.77 (4) 2.45 (4) 3.218 (6) 172 (8) C12—H12⋯Br9i 0.95 2.83 3.672 (8) 148 C16—H16⋯Br5 0.95 2.97 3.666 (8) 131 C22—H22⋯Br10ii 0.95 2.81 3.470 (7) 127 C26—H26⋯Br6 0.95 2.81 3.718 (8) 160 C32—H32⋯Br4ii 0.95 2.97 3.882 (7) 162 C36—H36⋯Br6 0.95 3.02 3.697 (7) 130 C42—H42⋯Br2iii 0.95 3.09 3.896 (8) 143 C17—H17C⋯Br3iv 0.98 2.87 3.680 (7) 141 C27—H27B⋯Br3 0.98 2.90 3.666 (8) 136 C28—H28A⋯Br4 0.98 3.01 3.809 (7) 140 C48—H48B⋯Br6iv 0.98 3.02 3.694 (8) 127 C48—H48A⋯Br8 0.98 3.00 3.744 (8) 133 C18—H18A⋯Br9 0.98 2.98 3.955 (8) 174 C24—H24⋯Br9i 0.95 2.92 3.714 (7) 142 C14—H14⋯Br10ii 0.95 2.93 3.792 (7) 152 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) .

Table 12 Hydrogen-bond geometry (Å, °) for 4 D—H⋯A D—H H⋯A D⋯A D—H⋯A N11—H01⋯Br9 0.83 (3) 2.40 (3) 3.217 (5) 166 (5) N21—H02⋯Br9 0.84 (3) 2.50 (4) 3.286 (4) 157 (5) N31—H03⋯Br9 0.83 (3) 2.53 (4) 3.246 (5) 145 (5) C12—H12⋯Br7 0.95 2.95 3.740 (6) 141 C32—H32⋯Br6 0.95 2.87 3.769 (5) 159 C18—H18C⋯Br6i 0.98 3.00 3.942 (6) 162 C27—H27A⋯Br8iii 0.98 2.99 3.822 (5) 143 C34—H34⋯Br1iv 0.95 3.01 3.957 (5) 172 Symmetry codes: (i) ; (iii) ; (iv) .

In compound 1, polymorph 1a, within the formula unit (the asymmetric unit plus, if necessary, atoms generated by symmetry to form complete residues), a short Au1⋯Br3 contact of 3.4502 (3) Å, axial with respect to the ligand plane, connects the anion and cation, and may be considered a ‘coinage bond' (Daolio et al., 2021; Pizzi et al., 2022). The contact angles are Au1⋯Br3—Br2 102.48 (1) and Br1—Au1⋯Br3 87.03 (1)°. The ‘weak' hydrogen bond H12⋯Br2, also within the formula unit but not drawn explicitly in Fig. 1, is by far the shortest H⋯Br contact at 2.79 Å. The Br1⋯Br3(−x, 1 − y, 1 − z) contact of 3.4995 (4) Å, with angles Au1—Br1⋯Br3′ = 162.48 (1) and Br2—Br3⋯Br1′ = 135.46 (1)°, is presumably a halogen bond [see e.g. Metrangolo et al. (2008) or Cavallo et al. (2016)]. These three contacts combine to form a layer structure parallel to the ac plane (Fig. 7). The packing of the second polymorph 1b shows a similar contact within the formula unit to that of 1a, namely Au1⋯Br3 = 3.5486 (5) Å, with Au1⋯Br3—Br2 = 108.18 (2) and Br1—Au1⋯Br3 = 87.20 (1)°. There is also a short intra­cationic contact H22⋯Br2′ of 2.88 Å; Br2 accepts two equivalent such hydrogen bonds with an H⋯Br⋯H angle of 86°. However, there are no contacts of the type Br_anion⋯Br_cation; the shortest Br⋯Br contact is Br1⋯Br1(x, 1 − y, 2 − z) = 3.8024 (9) Å, with Au1—Br1⋯Br1′ = 125.38 (2)°, which in terms of length is at best a borderline contact. The contacts combine to form chains of residues parallel to the c axis (Fig. 8).

Figure 7 The packing of compound 1, polymorph 1a, viewed perpendicular to the ac plane. Dashed lines indicate Au⋯Br, Br⋯Br (thick) or H⋯Br (thin) contacts.

Figure 8 The packing of compound 1, polymorph 1b, viewed approximately parallel to the a axis (but slightly rotated horizontally). Dashed lines indicate Au⋯Br (thick) or H⋯Br (thin) contacts. Borderline Br⋯Br contacts (see text) are omitted.

Compound 2 is already known as a triclinic polymorph (P, Z = 2) with a topologically square, but distorted, network of tetra­bromido­aurate ions involving Au atoms at the corners and Au—Br⋯Br—Au units along the edges (Döring & Jones, 2016). The packing diagram as originally published stressed this network and deliberately excluded the cations, which are hydrogen bonded to bromide ligands. We remedy this deficiency here (Fig. 9). The packing of the new polymorph is entirely different; it involves three-centre hydrogen bonds Br1⋯H01⋯Br1′ with an angle of 87 (2)° at the hydrogen atom and an axial coinage bond Au1⋯Br1(1 − x + y, 2 − x,  + z) of 3.5023 (9) Å, in addition to the halogen bonds Br4⋯Br1(1 − x + y, 2 − x,  + z) = 3.6158 (13) Å (which completes an unusual three-centre inter­action between Au1, Br4 and Br1′) and Br2⋯Br3(2 − y, 2 + x − y, − + z) = 3.4290 (13) Å. To simplify the packing diagrams, the rather longer contact Br3⋯Br4(1 − y, 1 + x − y, − + z) = 3.8901 (14) Å has been omitted. The associated, mostly approximately linear, angles are: Au1—Br2⋯Br3′ = 170.65 (4), Au1—Br3⋯Br2′ = 163.68 (5), Au1—Br1⋯Br4′ = 167.75 (4) and Au1—Br1⋯Au1′ = 137.24 (3)°, with approximate right angles for e.g. Br1—Au1⋯Br1′, 82.32 (2)°. Within the three-centre triangle, the angles are 67.55 (3), 72.59 (4) and 39.86 (2)°, respectively, at Au1, Br4 and Br1′. A packing diagram viewed perpendicular to the ac plane (Fig. 10) shows three one-dimensional arrays of residues parallel to the threefold axis (horizontal), linked by Br2⋯Br3′ to form a layer. A further Br2⋯Br3′ contact links the layers thus formed in the third dimension (Fig. 11).

Figure 9 The packing of the previously known polymorph 2′ of compound 2 (Döring & Jones, 2016), viewed perpendicular to (011). Dashed lines indicate Br⋯Br contacts (thick) or hydrogen bonds (thin). The three independent Br⋯Br distances are Br1⋯Br3′ = 3.4751 (8), Br2⋯Br2′ = 3.6685 (13) and Br4⋯Br4′ = 3.6791 (12) Å.

Figure 10 Packing diagram of compound 2 (new polymorph) viewed perpendicular to the ac plane in the region y ≃ 1. Dashed lines indicated Au⋯Br and Br⋯Br inter­actions (thick) or hydrogen bonds (thin).

Figure 11 The packing of compound 2 (new polymorph) projected parallel to the c axis. Dashed lines indicate Au⋯Br and Br⋯Br inter­actions (thick) or hydrogen bonds (thin).

In polymorph a of compound 3, the most obvious substructure in the packing is a dimeric unit with twofold symmetry (Fig. 12) centred on the free bromide ion Br3, with contacts Br2⋯Br3 of 3.6097 (6) Å that augment the classical hydrogen bonds. The free bromide is thus involved in two hydrogen bonds and two Br⋯Br inter­actions. The relevant angles are Au1—Br2⋯Br3 = 172.24 (2), Br2⋯Br3⋯Br2(1 − x, y,  − z) = 78.52 (2) and H01⋯Br3⋯H01′ = 106 (2)°. Dimers are connected via further Br2⋯Br3 contacts to form a zigzag chain parallel to the c axis (Fig. 13). Polymorph b is more complex, with eight residues in the asymmetric unit (Fig. 5), which includes two hydrogen-bonded (3,5-LutH⋯)₂Br groupings to the free bromides Br9 and Br10, together with two tetra­bromido­aurate ions linked by the contact Br1⋯Br6; the second anion is also connected to a free bromide by the contact Br5⋯Br10. In contrast to 3a, the free bromide Br9 is thus involved in two hydrogen bonds only, whereas Br10 is involved in two hydrogen bonds and one Br⋯Br contact. Associated dimensions for the hydrogen bonded units are H02⋯Br9⋯H03 = 98 (2) and H02⋯Br10⋯H03 = 87 (2)°, and for the anions Br1⋯Br6 = 3.6451 (11), Br5⋯Br10 = 3.7036 (11) Å, Au1—Br1⋯Br6 = 127.16 (3), Br1⋯Br6—Au2 = 164.26 (4) and Au2—Br5⋯Br10 = 151.71 (3). A further contact between the anions is Br2⋯Br4(x,  − y, − + z) of 3.6543 (10) Å, with Au1—Br2⋯Br4′ = 152.57 (3) and Au1—Br4⋯Br2′ = 151.02 (3)°. The residues are thus linked to form a broad band (with width equal to the a axis length) parallel to c (Fig. 14).

Figure 12 The dimeric unit of compound 3, polymorph a, centred on the free bromide ion Br3. Dashed lines indicate Br⋯Br inter­actions (thick) or hydrogen bonds (thin).

Figure 13 The extended packing of compound 3, polymorph a, viewed parallel to the b axis. A chain of residues parallel to the c axis runs horizontally in the region x ≃ 0.5 (partial chains are shown in the regions x ≃ 0 and 1). Dashed lines indicate Br⋯Br inter­actions (thick) or hydrogen bonds (thin).

Figure 14 The packing of compound 3, polymorph b, viewed parallel to the b axis in the region y ≃ 0.75. Three broad bands of residues parallel to the c axis can be recognized. Dashed lines indicate Br⋯Br inter­actions (thick) or hydrogen bonds (thin).

The packing of 3b as seen in Fig. 14 seems to be comprehensible, if complicated. It would thus not be suspected that a whole class of packing inter­actions has not been shown, but this is indeed the case; inter­actions involving the aromatic rings have not yet been considered. For aromatic ring systems, stacking (π–π), C—H⋯π or halogen⋯π contacts may be present. These are not observed for structures 1–3a, but for 3b they become important. We use the following notation: ring n is the ring containing Nn1, and Cgn = centroid of ring n. Rings 1 and 2 align in parallel, with an inter­planar angle of 2.85 (6)°, a Cg1⋯Cg2 distance of 3.637 (4) Å and an offset of 1.15 Å. Furthermore, these rings stack with neighbouring tetra­bromido­aurate anions involving Au1, with Au1⋯Cg2 = 3.588 (3), Au1(−1 + x, y, z)⋯Cg1 =3.566 (3) Å, respective inter­planar angles of 2.69 (5) and 1.17 (3)° and respective offsets 0.51, 0.65 Å. The resulting pattern consists of infinite stacks with the repeating sequence (⋯[AuBr₄]⁻⋯lutidinium⋯lutidinium⋯) parallel to the a axis (Fig. 15). Angles along the stack are Cg1′⋯Au1⋯Cg2 = 173°, Cg2⋯Cg1⋯Au1′ = 156°, Cg1⋯Cg2⋯Au1 = 156°. Finally, Br7 is involved in a short Br⋯π contact of 3.313 (3) Å to Cg3(1 − x, 1 − y, 1 − z); this connects the region y ≃ 0.75 (as in Figs. 14 and 15) with that at y ≃ 0.25 (Fig. 16). Such contacts can be regarded as a type of halogen bond.

Figure 15 Stacking inter­actions in structure 3b with view direction etc. as in Fig. 14. Dashed lines indicate stacking inter­actions (thick) or Br⋯Br contacts (thin).

Figure 16 Br⋯π inter­actions in structure 3b shown as thick dashed lines. The view direction is again parallel to the b axis, but in the region y ≃ 0.5.

The asymmetric unit of compound 4 (Fig. 6) was chosen to include as many short contacts as possible between the seven residues. All three cations are hydrogen bonded to the free bromide Br9, which is also involved in the contact Br7⋯Br9, 3.7404 (8) Å, with Au3—Br7⋯Br9 = 168.48 (2)°. The anions at Au1 and Au3 are linked via Br3⋯Br8, 3.4990 (8) Å, with Au1—Br3⋯Br8 = 162.26 (2) and Au3—Br8⋯Br3 = 110.41 (2)°. The anion at Au2 is not involved in short contacts within the asymmetric unit (see below for its role in the extended packing) but it does accept a weak hydrogen bond H32⋯Br6 (not drawn explicitly in Fig. 6). Similarly, the anions at Au1 and Au2 connect with ring 1, with Au1⋯Cg1 = 3.653 (2), Br6⋯Cg1 = 3.637 (2) Å and Au1⋯Cg1⋯Br6 = 164°; the anion at Au1 is almost parallel to ring 1 [inter­planar angle 5.2 (2)°]. These contacts too are not drawn explicitly for the sake of clarity. Fig. 17 shows the extended packing of the anions. The anions at Au2 form a chain parallel to the a axis (horizontal in the Figure, top and bottom) via the contact Br5⋯Br5(−x, 1 − y, −z) = 3.4414 (10) Å, with Au2—Br5⋯Br5′ = 157.80 (3)°. The anions at Au1 form a similar chain, also parallel to the a axis, with Br2⋯Br4(−1 + x, y, z) = 3.5253 (7) Å, Au1—Br2⋯Br4′ = 151.01 (2) and Au1—Br4⋯Br2′ = 152.39 (2)°. The anions at Au3 combine with the free bromide Br9 to form a chain of Au₂Br₄ rings parallel to the a axis, via the contacts Br7⋯Br9 and the axial contact Au3⋯Br9(1 + x, y, z) = 3.8611 (6) Å. These chains link with those at Au1 via the contacts Br3⋯Br8 to form a broad ribbon of residues. Fig. 18 shows the same view, but modified to show just the central ribbon, including cations and hydrogen bonds. The ribbons are joined by the Br⋯π contact Br2(x, 1 + y, z)⋯Cg3 = 3.769 (2) Å.

Figure 17 The packing of structure 4 showing only the anions, viewed perpendicular to the ac plane. Dashed lines indicate Br⋯Br and Au⋯Br contacts. The atom Br8 is almost eclipsed by Au3.

Figure 18 The packing of structure 4 including the cations but omitting the anions at Au2, with the same view direction as in Fig. 17. Dashed lines indicate Br⋯Br and Au⋯Br contacts (thick) or hydrogen bonds (thin).

It is worth stressing that two less frequent types of secondary inter­action, namely halogen⋯π contacts (which may be considered as halogen bonds) and stacking of aromatic rings with planar anions, play a significant role in two of the structures described here. Yet these inter­actions can be difficult to find using standard programs and instructions. We used the ‘CENT/X' command in XP (Bruker, 1998) to find the centres of gravity (labelled by the program as X1A, B, C, etc.) of the rings, and then used these pseudo-atoms to search for contacts. Even then, contacts within the asymmetric unit do not stand out because they have no symmetry operator, and the contacts to the centres of gravity may not be drawn because these are defined by XP as carbon (scattering factor type 1); to avoid this problem, we redefined the pseudo-atoms X as nitro­gen. Our personal view is that XP remains one of the best graphics programs despite its age.

4. Database survey

The previous publication in this series (Döring & Jones, 2025) presented a survey of structures involving both halide and tetra­halogenidoaurate(III) ions. For the current paper, a search for structures with stacking of [AuX₄]⁻ anions and six-membered aromatic rings was performed. Ring atoms were restricted to C or N. The inter­planar angle was restricted to the range 0–5°, and the maximum distance between the gold atom and the centroid of the ring was originally set to 3.8 Å. This gave 20 hits. To restrict the hits to the shortest distances, the maximum distance was then reduced to 3.6 Å, whereby five hits remained. These were: 2-(pyrimidin-2-yl)pyrimidin-1-ium tetra­chlorido­aurate(III) (refcode AHIYEX; Chernyshev et al., 2015); N-{[4-(acetamido­meth­yl)-2,3,5,6-tetra­methyl­phen­yl]meth­yl}-1- hy­droxy­ethan-1-iminium tetra­chlorido­aurate(III) (FACGID; Shaffer et al., 2021); tri­phenyl­telluronium tetra­chlorido­aurate(III) (MIHSOL; Oilunkaniemi et al., 2001); di­chloro­(4,4′-dimethyl-2,2′-bi­pyridine)­gold tetra­chlorido­aurate(III) (NOKREM; Amani et al., 2014); and 6,6′′-dimethyl-2,2′:6′,2′′-terpyridin-1,1′′-di-ium bis­[tetra­chlorido­aurate(III)] monohydrate (TIRMAL; Bocian et al., 2019). In three of these publications, the stacking was not discussed (the focus of the publications lay elsewhere, and such inter­actions are not as easily recognized as, say, hydrogen bonds), but Shaffer et al. (2021) gave an extensive description of the stacking of FACGID (infinite stacks of alternating [AuCl₄]⁻ anions and durene rings) and its potential for extracting tetra­halogenidoaurates(III) using durene derivatives, and Amani et al. (2014) presented the stacking of NOKREM (infinite stacks of alternating [AuCl₄]⁻ anions and pyridine rings) in some detail. Tiekink & Zukerman-Schpector (2009) have published a review of stacking involving gold complexes, but this was restricted to C₆ rings.

The packing of AHIYEX (Fig. 19) involves a substructure in which pairs of offset-stacked [AuCl₄]⁻ anions with Au⋯Cl = 3.455 Å are flanked by bipyrimidinium cations (Au⋯Cg = 3.567 Å) to give stacks of four planes; offset stacking is a well-known feature of tri- or tetra­halogenidogold(III) centres, e.g. in (tht)AuCl₃ (Upmann et al., 2017). The stacks propagate in the direction [11]. The packing of MIHSOL was, justifiably, analysed in terms of Te⋯Cl contacts, but the structure also contains isolated Cg(phen­yl)⋯Au⋯Cg(phen­yl) stacks with distances of 3.525 and 3.736 Å and an angle of 175.9°. For TIRMAL, a ribbon substructure (Fig. 20) can be recognized that involves three Au⋯Cg inter­actions [Au1⋯Cg1 = 3.569, Au1⋯Cg3 = 3.487 and Au2⋯Cg2 = 3.645 Å (× 2)], so that each ring of the terpyridine system is involved. Cl⋯Cl contacts of 3.467 Å also contribute to the ribbon.

Figure 19 The packing of AHIYEX (Chernyshev et al., 2015) drawn using the deposited coordinates, viewed perpendicular to (011). Dashed lines indicate Au⋯Cg or Au⋯Cl contacts. The space group is P and all atoms lie on general positions.

Figure 20 The packing of TIRMAL (Bocian et al., 2019) drawn using the deposited coordinates, viewed perpendicular to (01). Dashed lines indicate Au⋯Cg (thick) or Cl⋯Cl (thin) contacts. The ribbons run parallel to the a axis. The z coordinates were reduced by 0.5 to give a better fit to the cell. The space group is P; atoms Au2 lie on inversion centres.

The searches employed the routine ConQuest (Bruno et al., 2002), part of Version 2024.3.0 of the Cambridge Database (Groom et al., 2016).

5. Synthesis and crystallization

Compounds 2, 3 (polymorph b), 4: 90 mg (0.247 mmol) of (tht)AuBr were added to 2 mL of 3,5-lutidine. The mixture was sonicated and the white solid allowed to settle. The supernatant solution was pipetted off and the solid, presumed to be [(3,5-Lut)₂Au][AuBr₂] (Döring & Jones, 2024b), was dissolved in 2 mL di­chloro­methane. The clear colourless solution was distributed over five ignition tubes and overlayered with various precipitants, before being stored in a refrigerator overnight. In the tube with diisopropyl ether as precipitant, well-formed red hexa­gonal blocks of 4 together with some red plates of 3b were found. We were unable to establish how the oxidation had taken place, because no bromine was added. Two possibilities would be aerial oxidation or disproportionation. For compound 2, the same method was used, but two drops of bromine were added to the di­chloro­methane solution before overlayering. In the tube with n-heptane as precipitant, red needles and prisms of 2 formed.

Compound 3 (polymorph a): [(3,5-Lut)₂Au][AuBr₂] was obtained as above, but from the supernatant solution, which was transferred to a round-bottomed flask and overlayered with petroleum ether until a permanent turbidity was observed. The solid product (26.8 mg) was dried under vacuum and dissolved in 2 mL of di­chloro­methane. After the addition of two drops of bromine, the solution was overlayered as above. In the tube using diisopropyl ether as precipitant, red blocks and plates of 3a formed.

Compounds 1a, 1b: [(3,5-Lut)₂Au][AuBr₂] was obtained as above, but on a larger scale; 151 mg (0.414 mmol) were dissolved by sonication in 8 mL di­chloro­methane. The flask was connected via an angled tube to a further flask, containing 10 mL of di­chloro­methane and excess bromine, to allow slow diffusion. After one month, the solution had become red, and large red crystals had formed on the walls of the flask. This was then disconnected from the bromine solution and allowed to stand for a further month, by which time the solvent had evaporated. A red block was investigated and led to structure 1b. There were also a few smaller red blocks of a slightly different appearance, which proved to be the other polymorph 1a. A satisfactory analysis was obtained: Calculated C 20.74, H 2.24, N 3.45; found C 20.78, H 2.21, N 3.57%.

More details are given in the PhD thesis of CD (Döring, 2016).

6. Refinement

Details of the measurements and refinements are given in Table 13. Structures were refined anisotropically on F². Data for 3b are weak (with a correspondingly high value of R_int) but establish the existence of the second polymorph of 3. Hydrogen atoms of the NH groups were refined freely. For compounds 3b and 4, N—H distances were restrained to be approximately equal (command ‘SADI') and a common isotropic U value was employed for the NH hydrogen atoms. Hydrogen atoms of the lutidine rings were included at calculated positions and refined using a riding model with C—H = 0.95 Å. Methyl groups were included as idealized rigid groups with C—H = 0.98 Å and H—C—H = 109.5°, and were allowed to rotate but not tip (command ‘AFIX 137'), but the convergence was in many cases slow, and the methyl hydrogen positions should be inter­preted with caution (see below). U values of the hydrogen atoms were fixed at 1.5 × U_eq of the parent carbon atoms for methyl groups and 1.2 × U_eq of the parent carbon atoms for other hydrogens. For structures 1b and 3b, the second weighting parameter b oscillated over a small range. Structures 1b and 2 crystallize only by chance in Sohncke space groups; the compounds are achiral.

Table 13 Experimental details   1a 1b 2 Crystal data Chemical formula [AuBr2(C7H9N)2](Br3) [AuBr2(C7H9N)2](Br3) (C7H10N)[AuBr4] Mr 810.82 810.82 624.77 Crystal system, space group Triclinic, P Orthorhombic, C2221 Trigonal, P32 Temperature (K) 100 100 100 a, b, c (Å) 7.4459 (4), 8.9211 (6), 9.4090 (6) 9.42043 (16), 15.8371 (2), 13.7492 (2) 10.0289 (4), 10.0289 (4), 11.2031 (5) α, β, γ (°) 106.488 (6), 101.605 (5), 112.778 (7) 90, 90, 90 90, 90, 120 V (Å3) 517.23 (6) 2051.28 (6) 975.83 (9) Z 1 4 3 Radiation type Mo Kα Mo Kα Mo Kα μ (mm−1) 16.77 16.91 23.55 Crystal size (mm) 0.20 × 0.18 × 0.15 0.2 × 0.1 × 0.05 0.1 × 0.05 × 0.01   Data collection Diffractometer Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Absorption correction Multi-scan (CrysAlis PRO; Rigaku OD, 2014) Multi-scan (CrysAlis PRO; Rigaku OD, 2014) Multi-scan (CrysAlis PRO; Rigaku OD, 2014) Tmin, Tmax 0.321, 1.000 0.234, 1.000 0.413, 1.000 No. of measured, independent and observed [I > 2σ(I)] reflections 27639, 3076, 2938 112533, 3158, 3084 25086, 3312, 2979 Rint 0.033 0.052 0.071 θ values (°) θmax = 31.0, θmin = 2.4 θmax = 31.1, θmin = 2.5 θmax = 29.3, θmin = 2.4 (sin θ/λ)max (Å−1) 0.725 0.727 0.688   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.019, 0.040, 1.10 0.018, 0.037, 1.07 0.027, 0.036, 0.97 No. of reflections 3076 3158 3312 No. of parameters 106 105 124 No. of restraints 0 0 1 H-atom treatment H-atom parameters constrained H-atom parameters constrained H atoms treated by a mixture of independent and constrained refinement Δρmax, Δρmin (e Å−3) 1.39, −0.97 1.37, −1.05 0.98, −1.17 Extinction method Fc* = kFc[1+0.001xFc2λ3/sin(2θ)]-1/4 (SHELXL2019/3; Sheldrick, 2015) None None Extinction coefficient 0.0035 (2) – – Absolute structure – Flack x determined using 1294 quotients [(I+)−(I−)]/[(I+)+(I−)] (Parsons et al., 2013) Flack x determined using 1316 quotients [(I+)−(I−)]/[(I+)+(I−)] (Parsons et al., 2013) Absolute structure parameter – −0.028 (3) −0.026 (8)   3a 3b 4 Crystal data Chemical formula (C7H10N)2[AuBr4]Br (C7H10N)2[AuBr4]Br (C7H10N)3[AuBr4]2Br Mr 812.84 812.84 1437.60 Crystal system, space group Monoclinic, C2/c Monoclinic, P21/c Triclinic, P Temperature (K) 100 100 100 a, b, c (Å) 15.56307 (10), 9.5783 (4), 16.2371 (11) 10.5702 (4), 24.8303 (11), 16.4823 (7) 8.1261 (4), 12.0375 (5), 18.0076 (11) α, β, γ (°) 90, 119.625 (9), 90 90, 98.256 (4), 90 90.532 (4), 94.151 (5), 103.359 (4) V (Å3) 2104.0 (2) 4281.1 (3) 1708.68 (15) Z 4 8 2 Radiation type Mo Kα Mo Kα Mo Kα μ (mm−1) 16.49 16.20 19.12 Crystal size (mm) 0.1 × 0.05 × 0.03 0.11 × 0.11 × 0.03 0.15 × 0.10 × 0.05   Data collection Diffractometer Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Absorption correction Multi-scan (CrysAlis PRO; Rigaku OD, 2014) Multi-scan (CrysAlis PRO; Rigaku OD, 2014) Multi-scan (CrysAlis PRO; Rigaku OD, 2014) Tmin, Tmax 0.426, 1.000 0.330, 1.000 0.256, 1.000 No. of measured, independent and observed [I > 2σ(I)] reflections 29892, 3043, 2496 206035, 10607, 7996 86859, 8153, 6751 Rint 0.080 0.171 0.088 θ values (°) θmax = 30.0, θmin = 2.6 θmax = 28.3, θmin = 2.1 θmax = 27.9, θmin = 2.3 (sin θ/λ)max (Å−1) 0.704 0.667 0.658   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.030, 0.046, 1.08 0.048, 0.079, 1.05 0.031, 0.053, 1.03 No. of reflections 3043 10607 8153 No. of parameters 109 418 336 No. of restraints 0 6 3 H-atom treatment H atoms treated by a mixture of independent and constrained refinement H atoms treated by a mixture of independent and constrained refinement H atoms treated by a mixture of independent and constrained refinement Δρmax, Δρmin (e Å−3) 0.95, −0.92 1.38, −1.11 1.33, −1.16 Extinction method Fc* = kFc[1+0.001xFc2λ3/sin(2θ)]-1/4 (SHELXL2019/3; Sheldrick, 2015) None Fc* = kFc[1+0.001xFc2λ3/sin(2θ)]-1/4 (SHELXL2019/3; Sheldrick, 2015) Extinction coefficient 0.00018 (2) – 0.00037 (2) Computer programs: CrysAlis PRO (Rigaku OD, 2014, 2024), SHELXS97 (Sheldrick, 2008), SHELXL2019/3 (Sheldrick, 2015), XP (Bruker, 1998) and publCIF (Westrip, 2010).

checkCIF alerts: For compound 3a, the cell as originally determined (at a time when C-centred monoclinic settings were preferred to I-centred) can be transformed by the matrix ( 0 0 / 0 0 / 1 0 1) to an I-centred cell with a = 15.567, b = 9.578, c = 16.007 Å and β = 118.11°, space group I2/a. The β angle is slightly smaller than that of the original cell, which is thus formally non-reduced, causing checkCIF alert G ‘PLAT158'. The positions of the methyl hydrogens at C17 were assigned using ‘AFIX 137', which detected three clear maxima in the residual electron density. Nevertheless, the refinement converged slowly and checkCIF found negative electron density at the hydrogen positions (alert G ‘PLAT977'. It is possible that this methyl group is rotationally disordered. For compound 3b, the asymmetric unit was chosen to maximize the number of contacts contained therein. This leads to a position for the lutidine at N41 with most x coordinates > 1 and thus a centre of gravity outside the unit cell, which causes a checkCIF alert G ‘PLAT790'. Despite this alert, we prefer the chosen position.