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; several tetra­halogenidoaurate(III) salts of protonated amines have also been included. The previous part (Part 19; Döring & Jones, 2025b) presented some 3,5-lutidine derivatives; general comments given there apply to the current paper as well. Background material was given in Parts 18 and (especially) 12 of this series (Döring & Jones, 2025a, 2023).

Here we present the structures of the following picoline (methyl­pyridine, abbreviated to Pic) or lutidine (di­methyl­pyridine, abbreviated to Lut) derivatives: 2-picolinium tetra­chlorido­aurate(III), (2-PicH)[AuCl₄], 1 and tetrabromidoaurate(III), (2-PicH)[AuBr₄], 2; bis­(2-picolinium) tetra­bromido­aurate(III) bromide, (2-PicH)₂[AuBr₄]Br, 3; 3-picolinium tetra­bromido­aurate(III), (3-PicH)[AuBr₄], 4; trans-di­bromido­bis­(4-picoline)gold(III) tetra­bromido­aurate(III) nitro­methane mono­solvate, [(4-Pic)₂AuBr₂](AuBr₄](CH₃NO₂), 5; 4-picolinium tetra­bromido­aurate(III), (4-PicH)[AuBr₄], 6 and 2,4-lutidinium tetra­bromido­aurate(III), (2,4-LutH)[AuBr₄], 7.

2. Structural commentary

All compounds except the nitro­methane solvate 5 crystallize solvent-free. In the Figures (Figs. 1–7), 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. All ellipsoids are drawn at the 50% level. Selected mol­ecular dimensions are shown in Tables 1–7.

Table 4 Selected geometric parameters (Å, °) for 4 Au1—Br1 2.4241 (6) Au2—Br3 2.4207 (6) Au1—Br2 2.4284 (6) Au2—Br4 2.4251 (6)         Br1i—Au1—Br1 180.0 Br3—Au2—Br4 90.11 (2) Br1—Au1—Br2 89.68 (2) Br3—Au2—Br4ii 89.89 (2) Br1—Au1—Br2i 90.33 (2) Br4—Au2—Br4ii 180.0 Br2—Au1—Br2i 180.0 C12—N11—C16 123.5 (6) Br3ii—Au2—Br3 180.0     Symmetry codes: (i) ; (ii) .

Table 5 Selected geometric parameters (Å, °) for 5 Au1—N11 2.032 (8) Au3—Br3 2.4130 (12) Au1—Br1 2.4220 (10) Au3—Br4 2.4201 (12) Au2—N21 2.019 (8) Au3—Br6 2.4257 (12) Au2—Br2 2.4214 (11) Au3—Br5 2.4258 (12)         N11i—Au1—N11 180.0 Br4—Au3—Br6 176.54 (5) N11—Au1—Br1 89.7 (2) Br3—Au3—Br5 176.38 (4) N11—Au1—Br1i 90.3 (2) Br4—Au3—Br5 90.39 (4) Br1—Au1—Br1i 180.0 Br6—Au3—Br5 89.81 (4) N21ii—Au2—N21 180.0 (4) C16—N11—C12 120.3 (9) N21—Au2—Br2 90.3 (2) C16—N11—Au1 120.8 (7) N21—Au2—Br2ii 89.7 (2) C12—N11—Au1 118.9 (6) Br2—Au2—Br2ii 180.0 C22—N21—C26 119.5 (9) Br3—Au3—Br4 89.83 (4) C22—N21—Au2 120.9 (7) Br3—Au3—Br6 90.19 (4) C26—N21—Au2 119.5 (7) Symmetry codes: (i) ; (ii) .

Table 6 Selected geometric parameters (Å, °) for 6 Au1—Br1 2.4240 (6) Au2—Br3 2.4282 (6) Au1—Br2 2.4282 (6) Au2—Br4 2.4340 (6)         Br1i—Au1—Br1 180.0 Br3—Au2—Br4 90.21 (2) Br1—Au1—Br2 89.23 (2) Br3—Au2—Br4ii 89.79 (2) Br1—Au1—Br2i 90.77 (2) Br4—Au2—Br4ii 180.0 Br2—Au1—Br2i 180.0 C12—N11—C16 122.9 (7) Br3ii—Au2—Br3 180.0 (3)     Symmetry codes: (i) ; (ii) .

Figure 1 The asymmetric unit of compound 1 in the crystal. Ellipsoids are drawn at the 50% level for all structures. Dashed lines indicate Cl⋯Cl contacts or the shorter components of three-centre hydrogen bonds (thick) or the longer such components (thin).

Figure 2 The asymmetric unit of compound 2 in the crystal. Dashed lines indicate an Au⋯Br contact (thick) or hydrogen bonds (thin).

Figure 3 The asymmetric unit of compound 3 in the crystal. Dashed lines indicate a Br⋯Br contact (thick) or hydrogen bonds (thin).

Figure 4 The asymmetric unit of compound 4 in the crystal, extended by symmetry to form complete anions. Dashed lines indicate a Br⋯Br contact (thick) or hydrogen bonds (thin).

Figure 5 The asymmetric unit of compound 5 in the crystal, extended by symmetry to form complete cations. Dashed lines indicate Au⋯Br or Br⋯Br contacts. The solvent mol­ecule is drawn as spherical atoms of arbitrary radius.

Figure 6 The asymmetric unit of compound 6 in the crystal, extended by symmetry to form complete anions. Dashed lines indicate a hydrogen bond (thin) or a Br⋯Br contact (thick).

Figure 7 The asymmetric unit of compound 7 in the crystal. Dashed lines indicate a three-centre hydrogen-bond system.

Compounds 1 and 2 both crystallize in P with Z = 4 but are not isotypic. Compound 3 crystallizes in P with Z = 2. All atoms of 1–3 lie on general positions. Compound 4 crystallizes in P2₁/c with Z = 4; there are two independent anions, each with inversion symmetry. Compounds 5 and 6 crystallize in P with Z = 2; both involve two independent anions, each with inversion symmetry. Compound 7 crystallizes in P2₁2₁2₁ with Z = 4.

All the gold(III) species show the expected square-planar geometry. The tetra­halogenidoaurate(III) anions are close to the expected 4/mmm local symmetry, whereby the Au—Br bond lengths lie in the range 2.4130 (12)–2.4340 (6) Å and the largest deviations from 90 and 180° angles are 1.1 and 4.5°, respectively. In the cation of compound 5, the Au—N and Au—Br bond lengths are, as expected, similar to those of the trans-[(3,5-Lut)₂AuBr₂] cation in its tribromide salt [Au—N 2.025 (2) and Au—Br 2.4174 (3) in the first and Au—N 2.020 (4), 2.032 (4), Au—Br 2.4090 (4) Å in the second polymorph; Döring & Jones, 2025b]. The angles between the gold(III) coordination plane and the picoline ring plane of 5 are 56.4 (2)° in the first cation and 58.3 (2)° in the second. The C—N—C angles of the lutidine ligands in 5 are close to 120°, whereas the corresponding angles of the picolinium and lutidinium cations in 1–4, 6 and 7 lie in the range 122.9 (7)–124.9 (11)°.

3. Supra­molecular features

In the packing diagrams, atom labels indicate atoms of the asymmetric unit. Hydrogen atoms of the ring CH groups are omitted; we subjectively assess the C—H⋯halogen contacts to be less important than N—H⋯halogen (except perhaps for the sole chloride derivative 1; see below). Clearly, there is an implicit contradiction in the description of packing in terms of a few selected contacts and the fact that the packing energies almost certainly involve significant contributions from a much larger number of van der Waals contacts such as H⋯H [cf. the comments of Dance (2003)]. In the text, primes (′) indicate previously defined or generalized symmetry operators. Hydrogen bonds are listed in Tables 7–14. The rings are numbered with respect to the first digit of the nitro­gen atom numbers; thus ring 2 is based on the nitro­gen atom N21. The abbreviation ‘Cgn’ refers to the centre of gravity of the ring n. For many contact types, there was no clear cutoff distance for a ‘significant’ contact/inter­action, and some borderline cases were arbitrarily omitted for clarity; some of these are commented on explicitly below.

Table 8 Hydrogen-bond geometry (Å, °) for 1 D—H⋯A D—H H⋯A D⋯A D—H⋯A N11—H01⋯Cl1 0.88 (3) 2.66 (3) 3.510 (4) 163 (4) N11—H01⋯Cl4 0.88 (3) 2.96 (4) 3.562 (4) 127 (3) N21—H02⋯Cl5 0.87 (3) 2.77 (3) 3.421 (3) 132 (3) N21—H02⋯Cl8 0.87 (3) 2.93 (3) 3.756 (4) 159 (3) C13—H13⋯Cl4i 0.95 2.88 3.756 (4) 154 C13—H13⋯Cl7i 0.95 2.96 3.639 (4) 129 C16—H16⋯Cl4 0.95 2.83 3.505 (5) 129 C16—H16⋯Cl7 0.95 2.74 3.621 (4) 154 C17—H17C⋯Cl7ii 0.98 2.86 3.691 (4) 144 C23—H23⋯Cl5iii 0.95 2.88 3.803 (4) 164 C25—H25⋯Cl3iv 0.95 2.93 3.811 (5) 156 C26—H26⋯Cl2iv 0.95 2.72 3.635 (4) 161 C26—H26⋯Cl5 0.95 2.88 3.484 (5) 123 C27—H27B⋯Cl2v 0.98 2.87 3.841 (4) 170 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) ; (v) .

Table 9 Hydrogen-bond geometry (Å, °) for 2 D—H⋯A D—H H⋯A D⋯A D—H⋯A N11—H01⋯Br4 0.88 2.62 3.422 (9) 153 N21—H02⋯Br5 0.88 2.60 3.369 (10) 147 C13—H13⋯Br2i 0.95 3.10 3.783 (11) 131 C16—H16⋯Br4ii 0.95 2.96 3.870 (11) 162 C17—H17A⋯Br1 0.98 3.04 3.800 (11) 136 C17—H17A⋯Br6iii 0.98 3.11 3.796 (10) 128 C17—H17C⋯Br1iii 0.98 3.03 3.706 (11) 127 C23—H23⋯Br7i 0.95 3.11 3.765 (11) 128 C25—H25⋯Br3i 0.95 2.95 3.894 (13) 171 C26—H26⋯Br5iv 0.95 2.86 3.811 (13) 177 C27—H27A⋯Br1iii 0.98 3.08 3.940 (13) 147 C27—H27B⋯Br4v 0.98 3.03 3.994 (13) 169 C27—H27C⋯Br8vi 0.98 3.05 3.814 (13) 136 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) ; (v) ; (vi) .

Table 10 Hydrogen-bond geometry (Å, °) for 3 D—H⋯A D—H H⋯A D⋯A D—H⋯A N11—H01⋯Br5 0.80 (4) 2.43 (4) 3.225 (3) 172 (6) N21—H02⋯Br5 0.80 (4) 2.39 (4) 3.191 (4) 173 (5) C13—H13⋯Br1i 0.95 3.13 3.961 (4) 146 C15—H15⋯Br2ii 0.95 3.07 3.941 (4) 152 C16—H16⋯Br1 0.95 3.08 3.614 (4) 117 C16—H16⋯Br5iii 0.95 2.91 3.751 (4) 148 C17—H17B⋯Br1i 0.98 2.99 3.932 (4) 162 C17—H17C⋯Br2iii 0.98 3.02 3.758 (4) 133 C26—H26⋯Br2iv 0.95 2.81 3.602 (4) 142 C27—H27A⋯Br3iii 0.98 3.00 3.800 (5) 140 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) .

Table 11 Hydrogen-bond geometry (Å, °) for 4 D—H⋯A D—H H⋯A D⋯A D—H⋯A N11—H01⋯Br1 0.93 (6) 2.61 (6) 3.432 (5) 149 (5) N11—H01⋯Br2 0.93 (6) 2.84 (6) 3.539 (6) 134 (5) C12—H12⋯Br3 0.95 2.93 3.874 (7) 175 C15—H15⋯Br1iii 0.95 2.87 3.724 (7) 151 C16—H16⋯Br2 0.95 3.05 3.637 (7) 122 C16—H16⋯Br4iv 0.95 2.93 3.726 (7) 143 Symmetry codes: (iii) ; (iv) .

Table 12 Hydrogen-bond geometry (Å, °) for 5 D—H⋯A D—H H⋯A D⋯A D—H⋯A C12—H12⋯Br4iii 0.95 2.99 3.771 (11) 141 C12—H12⋯Br5iii 0.95 3.06 3.629 (10) 120 C13—H13⋯O2iv 0.95 2.54 3.240 (15) 131 C15—H15⋯Br2v 0.95 2.96 3.802 (10) 149 C16—H16⋯Br6vi 0.95 3.05 3.826 (10) 140 C22—H22⋯Br5ii 0.95 3.04 3.766 (11) 135 C23—H23⋯Br1vii 0.95 3.06 3.883 (9) 146 C26—H26⋯Br6 0.95 3.07 3.665 (10) 122 C26—H26⋯O1 0.95 2.39 3.235 (16) 147 C1—H1B⋯Br3vi 0.98 3.03 3.737 (17) 130 Symmetry codes: (ii) ; (iii) ; (iv) ; (v) ; (vi) ; (vii) .

Table 13 Hydrogen-bond geometry (Å, °) for 6 D—H⋯A D—H H⋯A D⋯A D—H⋯A N11—H01⋯Br2 0.91 (11) 3.04 (10) 3.628 (7) 124 (8) N11—H01⋯Br3 0.91 (11) 2.56 (11) 3.395 (7) 154 (9) C12—H12⋯Br1 0.95 2.96 3.872 (8) 160 C15—H15⋯Br1iii 0.95 3.07 3.764 (7) 132 C16—H16⋯Br2iv 0.95 2.96 3.890 (7) 166 C13—H13⋯Br4v 0.95 3.04 3.750 (6) 133 Symmetry codes: (iii) ; (iv) ; (v) .

Table 14 Hydrogen-bond geometry (Å, °) for 7 D—H⋯A D—H H⋯A D⋯A D—H⋯A N11—H01⋯Br4 0.82 (8) 2.82 (7) 3.435 (7) 134 (7) N11—H01⋯Br1 0.82 (8) 2.92 (8) 3.527 (6) 133 (7) C15—H15⋯Br2i 0.95 2.96 3.622 (7) 128 C18—H18B⋯Br2ii 0.98 2.94 3.780 (8) 145 C16—H16⋯Br3i 0.95 3.03 3.981 (7) 177 C18—H18A⋯Br3iii 0.98 2.93 3.903 (7) 174 C17—H17A⋯Br4iv 0.98 3.01 3.862 (8) 146 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) .

Our recent investigations have analysed packing patterns in terms of secondary inter­actions such as hydrogen bonds, halogen bonds [for reviews see e.g. Cavallo et al. (2016) or Metrangolo et al. (2008)] or coinage bonds [a recent formalization, in terms of π holes at the gold atom, of the axial contacts to square-planar gold(III) centres; Daolio et al. (2021) and Pizzi et al., 2022)]. Less common features (Döring & Jones, 2025b) are the mixed stacking of aromatic rings and tetra­halogenidoaurate ions, and contacts of the type halogen⋯π (which may be regarded as a special form of halogen bond).

The asymmetric unit of compound 1 (Fig. 1) was chosen to include the two asymmetric three-centre hydrogen-bond systems of the type N—H⋯(Cl,Cl), together with the short contact Cl4⋯Cl7 [3.3947 (13) Å, with angles Au1—Cl4⋯Cl7 = 157.89 (5) and Au2—Cl7⋯Cl4 = 154.42 (4)°]. Another such contact is Cl2⋯Cl5(−1 + x, y, 1 + z) [3.4586 (14) Å, with Au1—Cl2⋯Cl5’ = 153.16 (4) and Au2—Cl5⋯Cl2′ = 152.76 (5)°]. These combine with the short axial contacts (coinage bonds) Au1⋯Cl6(1 − x, −y, 1 − z) = 3.5947 (10) and Au2⋯Cl3(1 − x, 1 − y, 1 − z) = 3.3963 (10) Å to form a layer structure parallel to (101) (Fig. 8). The Cl⋯Cl linkages run horizontally in Fig. 8, parallel to [10], whereas the coinage bonds link the anions vertically (parallel to the b axis). The structure also involves a considerable number of ‘weak’ C—H⋯Cl hydrogen bonds, notably the three-centre system H16⋯(Cl4, Cl7) and one component of the double-acceptor system (H02, H26)⋯Cl5 within the asymmetric unit, but these are not included in Fig. 1 or Fig. 8.

Figure 8 Packing diagram of compound 1, viewed perpendicular to (101). Dashed lines indicate Cl⋯Cl or Au⋯Cl contacts (thick) or hydrogen bonds (thin). The Cl⋯π contacts are shown as faint dotted lines (although some are obscured in this view direction, as are the labelled atoms Cl2 and Cl7).

The chlorine atoms Cl2 and Cl7 are also involved in the short Cl⋯π contacts Cl2⋯Cg2(1 − x, 1 − y, 1 − z) = 3.398 (2) and Cl7⋯Cg1(1 − x, −y, 1 − z) = 3.399 (2) Å, with Au—Cl⋯Cg angles of 121.3 and 117.5°, respectively. Fig. 9 shows the layer of Fig. 8 viewed from the side (parallel to the b axis), showing the appreciable thickness of the layers and the linking role of the Cl⋯π contacts. The significantly longer contacts Cl1⋯Cg1(−x, −y, 1 − z) = 3.673 (2) and Cl5⋯Cg2(1 − x, 1 − y, −z) = 3.695 (2) Å may play a minor structural role in linking the layers, but have been omitted from the packing diagrams.

Figure 9 The packing of compound 1 projected parallel to the b axis (same atoms as in Fig. 8), showing the linking role of the Cl⋯π inter­actions.

The asymmetric unit of compound 2 (Fig. 2) was chosen to contain the two classical hydrogen bonds of the type N—H⋯Br and the coinage bond Au1⋯Br6 [3.6926 (13) Å]. There are also two further such contacts [Au1⋯Br8(x, y, 1 + z) = 3.7660 (12) and Au2⋯Br1(1 − x, 1 − y, 1 − z) = 3.5899 (11) Å] and two short bromine-bromine contacts [Br4⋯Br4(−x, 1 − y, 2 − z) = 3.576 (2) Å, with Au1—Br4⋯Br4′ = 146.85 (6)°, and Br5⋯Br5(−x, 1 − y, 1 − z) = 3.622 (2) Å, with Au2—Br5⋯Br5’ = 144.27 (6)°]. The two coinage bonds at Au1 link the anions to form chains parallel to the c axis, and these chains are cross-linked by the remaining contacts to form a layer structure parallel to the ac plane (Fig. 10). As for 1, the layer also contains halogen⋯π contacts, namely Br7⋯Cg1(1 − x, 1 − y, 1 − z) = 3.499 (4) and Br2⋯Cg2(1 − x, 1 − y, 1 − z) = 3.468 (6) Å (with Au—Br⋯Cg angles of 126.9 and 119.6°, respectively) and the somewhat longer Br5⋯Cg1(-x, 1 − y, 1 − z) = 3.703 (4) and Br4⋯Cg2(-x, 1 − y, 1 − z) = 3.764 (5) Å, all within the layer. To avoid overloading the packing diagram, just one of each contact (those involving the rings of the asymmetric unit) has been included explicitly. A projection of the structure parallel to the c axis (omitting Br⋯π contacts; Fig. 11) shows the corrugated nature of the layers. The contacts Br2⋯Br2(1 − x, 2 − y, 1 − z) = 3.813 (2) and Br7⋯Br7(1 − x, 2 − y, −z) 3.872 (2) Å between the layers may be too long to be significant.

Figure 10 The packing of compound 2, viewed perpendicular to the ac plane. Dashed lines indicate Br⋯Br or Au⋯Br contacts (thick) or hydrogen bonds (thin). Four representative Br⋯π inter­actions (involving the parent rings at N11 and N21) have also been included as thin dashed lines.

Figure 11 A layer of compound 2, projected parallel to the c axis. Cations and Br⋯π inter­actions are omitted.

The asymmetric unit of compound 3 (Fig. 3) contains two classical N—H⋯Br hydrogen bonds and the contact Br1⋯Br5 [3.7399 (6) Å, with Au1—Br1⋯Br5 = 150.30 (2)°]; the free bromide ion Br5 is involved in all three of these inter­actions. The coinage bond Au1⋯Br5(−x, 2 − y, 1 − z) = 3.7451 (5) Å] then leads to rings of composition Au₂Br₄, which are further linked by the contact Br3⋯Br3(−x, 3 − y, −z) = 3.5948 (8) Å, with Au1—Br3⋯Br3′ = 153.53 (2)°, to form chains of residues parallel to [01] (Fig. 12).

Figure 12 The packing of compound 3, viewed perpendicular to (011), showing chains of residues parallel to [01]. Dashed lines indicate Au⋯Br and Br⋯Br contacts (thick) or hydrogen bonds (thin).

The asymmetric unit of compound 4 (extended by symmetry to generate complete ions; Fig. 4) contains the three-centre hydrogen bond N11—H01⋯(Br1, Br2) and the contact Br1⋯Br3 [3.4957 (8) Å, with Au1—Br1⋯Br3 = 162.53 (3) and Au2—Br3⋯Br1 = 155.20 (3)°]. Together with the two inversion operators corresponding to the special positions of the gold atoms, this generates a chain of residues parallel to [101] in the region y ≃ 0. Three such chains are shown in Fig. 13. The linear moieties Br2—Au1—Br2′ and Br4—Au2—Br4′ are inclined to (10) in the opposite sense for the central chain compared to the other two chains. Adjacent chains are linked by the Br⋯π contact Br1⋯Cg(1 − x, − + y,  − z) = 3.528 (2) Å, with Au—Br⋯Cg = 111.5°. The packing is further complicated by a series of borderline contacts: the coinage bonds Au1⋯Br4′ = 3.8290 (6) and Au2⋯Br2′ = 3.8282 (6) Å (operator 1 − x, − + y,  − z) and the contact Br2⋯Br4(x,  − y,  + z) = 3.8374 (9) Å, which connect the anions to form a three-dimensional network. There is also a somewhat longer Br⋯π contact, namely Br3⋯Cg(−x, − + y,  − z) = 3.767 (2) Å.

Figure 13 The packing of compound 4, viewed perpendicular to (10), showing chains of residues parallel to [101]. Dashed lines indicate Br⋯Br contacts (thick) or hydrogen bonds (thin). Contacts of the type Br⋯π are not drawn explicitly, because they are almost parallel to the view direction; however, these can be recognized e.g. for the ring based on N11, from the ring centre to the bromine atom overlapped with the left-hand edge of this ring. This is a simplified view in which several borderline contacts are not included (see text).

The asymmetric unit of compound 5 consists of two half cations and one anion (Fig. 5), and includes the short contact Br1⋯Br5 [3.5058 (14) Å, with Au1—Br1⋯Br5 = 158.16 (5) and Au3—Br5⋯Br1 = 125.72 (4)°] and the coinage bond Au2⋯Br6 = 3.3709 (11) Å. Further contacts Br2⋯Br6(−1 + x, y, z) = 3.5407 (15) Å [with Au2—Br2⋯Br6′ = 166.48 (5) and Br2⋯Br6′—Au3′ = 106.50 (4)°] link the anions and cations to form a corrugated layer structure (Fig. 14) parallel to the ac plane, involving six-membered Au₂Br₄ rings (with two Au—Br bonds from cations, two Au⋯Br and two Br⋯Br contacts) and ten-membered Au₄Br₆ rings (with four Au—Br bonds from anions and two from cations, two Au⋯Br and two Br⋯Br contacts). The atoms Br5 and Br6 take part in both types of ring, and each has two short contacts (Au⋯Br and Br⋯Br), thus attaining an approximately trigonal–planar geometry; cf. the unusually narrow Br⋯Br—Au angles at these atoms (see above), which differ greatly from the usual approximately linear values. A closely analogous pattern was observed for the triclinic polymorph of the related compound trans-di­bromido­bis­(3,5-lutidine)gold(III) tribromide (Döring & Jones, 2025b). A projection of the structure of 5 parallel to the a axis (Fig. 15) shows the corrugation, with the anions constituting the fold regions. In view of the poorly resolved nature of the solvent mol­ecule, we do not comment on it in detail, except to point out that its oxygen atoms accept two short hydrogen bonds from CH donors.

Figure 14 Packing diagram of compound 5 (without solvent), showing the layer structure parallel to the ac plane; the view direction is perpendicular to that plane. Thick dashed lines indicate Br⋯Br or Au⋯Br contacts.

Figure 15 The packing of compound 5 projected parallel to the a axis, showing the corrugation of the layer.

The asymmetric unit of compound 6 contains the contact Br2⋯Br3 [3.5839 (9) Å, with Au1—Br2⋯Br3 very narrow at 82.96 (2) and Au2—Br3⋯Br2 = 164.03 (3)°], together with the classical hydrogen bond N11—H01⋯Br3. The hydrogen bonding might be regarded as a three-centre system including a longer branch H01⋯Br3; however, the position of H01 is not well-determined, with s.u.'s of ca. 0.1 Å for the H⋯Br distances. In combination with the coinage bond Au2⋯Br2(1 − x, 1 − y, 2 − z), 3.3777 (6) Å, a layer structure parallel to the ab plane is formed (Fig. 16), which consists of six- and ten-membered rings forming a pattern topologically analogous to that of 5, despite the major chemical differences between 5 and 6 (e.g. the presence of coordinated or protonated pyridine rings). However, the angles in the rings of the two layers differ appreciably; particularly notable in 6 are the angles Au1—Br2⋯Br3 and the nearly linear Au1—Br2⋯Au2′ [162.50 (2)°]. There are also two Br⋯π contacts, namely Br4⋯Cg(1 + x, y, z) = 3.694 (3) Å, with Au2—Br4⋯Cg′ = 113.1°, and the perhaps borderline Br1⋯Cg(1 − x, 1 − y, 1 − z) = 3.8240 (3) Å, with Au1—Br1⋯Cg′ = 126.7°. These lie within the layers but are not drawn in Fig. 16 because they are almost parallel to the view direction. Fig. 17 shows these contacts clearly, together with the rather long Br1⋯Br4(1 − x, 1 − y, 1 − z) contact of 3.7167 (10) Å, with Au1—Br1⋯Br4′ = 155.27 (3) and Au2—Br4⋯Br1′ = 164.43 (3)°, which links the layers at z ≃ 0 and 1.

Figure 16 Packing diagram of compound 6, showing the layer structure parallel to the ab plane; the view direction is perpendicular to that plane in the region z ≃ 1. Dashed lines indicate Br⋯Br or Au⋯Br contacts (thick) or hydrogen bonds (thin).

Figure 17 The packing of compound 6 projected parallel to the b axis, showing the Br⋯π contacts (open dashed bonds) and the linkage of the layers at z ≃ 0 and 1 by the contacts Br1⋯Br4.

The packing of compound 7 displays fewer striking features than the other structures. For structures in space group P2₁2₁2₁, it is often difficult to produce easily inter­pretable packing diagrams, because the combination of mutually perpendicular 2₁ axes seldom produces motifs that are easily shown in two dimensions. This generalization also holds for 7. The asymmetric unit (Fig. 7) shows the three-centre classical hydrogen bond. This combines with the coinage bond Au1⋯Br3 (− + x,  − y, 1 − z) = 3.6391 (7) Å to produce a ribbon of residues parallel to the a axis, seen clearly running horizontally through the centre of Fig. 18. However, the further, longer, contacts Br1⋯Br4(1 − x,  + y,  − z) = 3.7854 (10), Br2⋯Br4( − x, 2 − y,  + z) = 3.8126 (9) and Br1⋯Cg(1 − x,  + y,  − z) = 3.735 (3) Å involve the other two screw axes. Only the peripheral Br⋯π contacts are also shown in Fig. 18. The Au1—Br1⋯Cg angle is extremely narrow at 77.2°, associated with an Au1⋯Cg distance of 3.980 (3) Å.

Figure 18 The packing of compound 7 viewed parallel to the b axis in the range y ≃ 0.75. Dashed lines indicate Au⋯Br contacts (thick) or hydrogen bonds (thin). The main ribbon of residues (see text) runs horizontally in the centre of the diagram; peripheral Br⋯π contacts (two further ribbons) are shown top and bottom as open dashed bonds.

The recent papers in this series have shown some uncommon packing motifs. We reported several examples of linear Au—X⋯X—Au groupings, where X = Cl or Br, in an earlier paper (Döring & Jones, 2016), and a literature search appeared in part 18 (Döring & Jones, 2025a). The first type of inter­action is reminiscent of the classical halogen bond C—X⋯X—C, for which two types were differentiated by Pedireddi et al. (1994) in terms of the C—X⋯X angles; type 1 with both angles approximately equal and type 2 with angles of approximately 90 and 180°. The latter were thought to be more significant, and were inter­preted in terms of a σ hole in the extension of one C—X bond. We are however not aware of any similar theoretical treatment of Au—X⋯X—Au contacts. Another motif is the stacking of pyridinium rings and square-planar [AuX₄]⁻ ions (where X = Cl or Br), for which a literature search was reported in the previous paper (Döring & Jones, 2025b). A third type of motif consists of Au—X⋯π contacts (generally with narrow angles at the X atom), for which we are also unaware of any theoretical analysis.

4. Database survey

The searches employed the routine ConQuest (Bruno et al., 2002), part of Version 2025.1.1 of the Cambridge Structural Database (Groom et al., 2016). In the first search, systems involving four-coordinate gold with two coordinated halogen atoms and two coordinated pyridines (including substituted pyridines) were sought. Only four compounds were found, all involving cations with a trans configuration at the gold atom.

The oldest such structure is the pyridine derivative trans-[Py₂AuCl₂]Cl·H₂O, part of the pioneering work of Strähle in establishing the structures of ‘simple’ gold complexes (refcode BENYEY; Adams & Strähle, 1982), later redetermined (BENYEY01) by Bowling et al. (2023). The structure [(3-Lut)₂AuCl₂]SbF₆ was included in Part 2 of this series (HILNOF; Jones & Ahrens, 1998). The ternary Au^III derivative [Py₂AuBr₂]·2[PyAuBr₃]·[AuBr₄] (WOQMEU; Peters et al., 2000) and its chlorine analogue (KILFIV; Bourosh et al., 2007) were also found. The two structures appear to be isotypic; curiously, the newer reference does not mention the older one.

In the second search, the shortest (< 3.5 Å) Br⋯π contacts from [AuBr₄]⁻ ions to aromatic six-membered rings (containing any combination of C and N atoms) were sought. This gave five hits; the first three involve nitro­gen heterocycles. In bis­(2,2′-bi­pyridine)­dibromido­gold(III) di­bromido­aurate(I) tetra­bromido­aurate(III) (AHOFAG; compound 10 in Chernyshev et al., 2015), the distance of 3.482 Å may correspond to a stacking inter­action of the anion and cation, with the Au—Br⋯π angle of 88.5° corresponding to an almost parallel orientation of the two moieties. In 2-(quinolin-2-yl)quinolinium tetra­bromido­aurate(III) (AHOGIP; compound 18, ibid.) the distance is 3.489 Å and the angle 98.1°. In di­bromido-(2,2′-bi­pyridine)­gold(III) tetra­bromido­aurate(III) (XEMCEY01; compound 11b in Hayoun et al., 2006) the distance is 3.424 Å and the angle rather wider at 120.6°. The final two hits involve phenyl rings; both come from our own work, but we did not report the Br⋯π contacts at the time. In 5-(diphen­yl(bromo)­phospho­nio)[2.2]para­cyclo­phane tetra­bromido­aurate(III) (BOKNOH; compound 5 in Upmann et al., 2019), the distance is 3.492 Å and the angle 164.6°, whereas in 1,1,3,3-tetra­phenyl-1,3-di­hydro-2,1,3-benzo­thiadi­phosphole-1,3-diium bromide tetra­bromido­aurate(III) di­chloro­methane hemisolvate (ODAWOH; compound 3 in Taouss & Jones, 2011; Fig. 19), the distance is 3.447 Å and the angle 156.9°. We note that the Au—Br⋯π angles differ greatly between systems involving heterocyclic or phenyl rings.

Figure 19 One formula unit of 1,1,3,3-tetra­phenyl-1,3-di­hydro-2,1,3-benzo­thiadi­phosphole-1,3-diium bromide tetra­bromido­aurate(III) di­chloro­methane hemisolvate (Taouss & Jones, 2011), excluding solvent, showing the short S⋯Br− and Au—Br⋯π contacts (full and open dashed bonds respectively); only the former were discussed at the time. The ensemble displays crystallographic inversion symmetry. The other independent formula unit shows no Br⋯π contacts, but is instead involved in Br⋯Cl contacts to the solvent mol­ecule.

5. Synthesis and crystallization

Compound 1: In an attempt to obtain single crystals of tri­chlorido­(2-picoline)gold(III), a sample was dissolved in di­chloro­methane and the solution was overlayered with diisopropyl ether. Yellow irregular blocks of 1 were obtained. Analysis: calculated C 16.65, H 1.86, N 3.24; found C 16.88, H 1.77, N 3.20%.

Compound 2: In an attempt to obtain single crystals of tri­bromido­(2-picoline)gold(III), 90 mg of bromido­(tetra­hydro­thio­phene)­gold(I) were added to 2 mL of 2-picoline and suspended overnight using an ultrasonic bath. The white solid product, assumed to be bis­(2-picoline)gold(I) di­bromido­aurate(I), was suspended in 2 mL of di­chloro­methane, and two drops of elemental bromine were added. The solution was distributed over five ignition tubes and overlayered with various precipitants. In the tube using diisopropyl ether, crystals of 2 in the form of red hexa­gonal plates were obtained. Analysis: calculated C 11.80, H 1.32, N 2.29; found C 12.00, H 1.32, N 2.44%.

Compound 3: A further attempt to obtain single crystals of tri­bromido­(2-picoline)gold(III), using slightly varied amounts, led to red plates of 3 when diisopropyl ether was used as precipitant.

Compound 4: Crystallization attempts analogous to those producing 2, but using 3-picoline, led to red blocks of 4. Analysis: calculated C 11.80, H 1.32, N 2.29; found C 12.11, H 1.40, N 2.41%.

Compound 5: In an attempt to obtain single crystals of tri­bromido­(4-picoline)gold(III), 40 mg of bis­(4-picoline)gold(I) di­bromido­aurate(I) were dissolved in 2.5 mL of nitro­methane, and 3 drops of elemental bromine were added. Crystallization attempts as above led to red plates of 5 when diethyl ether was used as precipitant.

Compound 6: A further attempt to obtain single crystals of tri­bromido­(4-picoline)gold(III), using di­chloro­methane as solvent (as above for 2), led to red plates of 6 when diethyl ether was used as precipitant.

More details are given in the PhD thesis of CD (Döring, 2016). However, details of the crystallization of 7 have unfortunately been lost.

6. Refinement

Details of the measurements and refinements are given in Table 15. Structures were refined anisotropically on F². Hydrogen atoms of the 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 methyl hydrogen-atom positions thus determined should be inter­preted with caution in the presence of heavy atoms. 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 hydrogen atoms.

Table 15 Experimental details   1 2 3 4 Crystal data Chemical formula (C6H8N)[AuCl4] (C6H8N)[AuBr4] (C6H8N)2[AuBr4]Br (C6H8N)[AuBr4] Mr 432.90 610.74 784.78 610.74 Crystal system, space group Triclinic, P Triclinic, P Triclinic, P Monoclinic, P21/c Temperature (K) 100 100 100 100 a, b, c (Å) 8.0764 (3), 9.0839 (3), 15.3667 (6) 9.9208 (5), 11.9072 (6), 12.2765 (7) 8.7050 (2), 9.1257 (4), 13.8767 (6) 8.1918 (3), 9.3458 (3), 16.1449 (6) α, β, γ (°) 87.792 (3), 76.132 (3), 85.391 (3) 65.423 (5), 70.506 (5), 68.459 (5) 77.246 (4), 80.023 (3), 61.718 (4) 90, 102.949 (4), 90 V (Å3) 1090.77 (7) 1198.31 (13) 943.79 (7) 1204.59 (8) Z 4 4 2 4 Radiation type Mo Kα Mo Kα Mo Kα Mo Kα μ (mm−1) 14.41 25.57 18.37 25.43 Crystal size (mm) 0.10 × 0.08 × 0.03 0.12 × 0.08 × 0.01 0.20 × 0.12 × 0.06 0.08 × 0.03 × 0.02   Data collection Diffractometer Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Absorption correction Multi-scan (CrysAlis PRO; Rigaku OD, 2020) Multi-scan (CrysAlis PRO; Rigaku OD, 2020) Multi-scan (CrysAlis PRO; Rigaku OD, 2020) Multi-scan (CrysAlis PRO; Rigaku OD, 2020) Tmin, Tmax 0.696, 1.000 0.497, 1.000 0.265, 1.000 0.328, 1.000 No. of measured, independent and observed [I > 2σ(I)] reflections 7091, 7091, 5430 5734, 5734, 3079 82101, 5671, 4933 38517, 2983, 2244 Rint – – 0.057 0.079 θ values (°) θmax = 30.0, θmin = 3.2 θmax = 28.3, θmin = 2.2 θmax = 31.0, θmin = 2.6 θmax = 28.3, θmin = 2.5 (sin θ/λ)max (Å−1) 0.703 0.667 0.725 0.667   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.022, 0.036, 0.85 0.039, 0.066, 0.78 0.030, 0.061, 1.05 0.031, 0.052, 1.04 No. of reflections 7091 5734 5671 2983 No. of parameters 228 238 191 117 No. of restraints 1 138 1 0 H-atom treatment H atoms treated by a mixture of independent and constrained refinement H-atom parameters constrained 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) 1.33, −0.99 1.65, −1.21 2.27, −1.89 1.05, −0.99   5 6 7 Crystal data Chemical formula [AuBr2(C6H7N)2][AuBr4]·CH3NO2 (C6H8N)[AuBr4] (C7H10N)[AuBr4] Mr 1120.69 610.74 624.77 Crystal system, space group Triclinic, P Triclinic, P Orthorhombic, P212121 Temperature (K) 101 100 100 a, b, c (Å) 7.5336 (4), 12.49946 (10), 12.74241 (10) 7.5701 (3), 9.5159 (5), 9.5653 (5) 8.8797 (3), 9.4081 (4), 15.5202 (5) α, β, γ (°) 84.400 (6), 89.908 (5), 86.012 (5) 112.616 (5), 104.788 (4), 96.401 (4) 90, 90, 90 V (Å3) 1191.26 (7) 597.79 (6) 1296.57 (8) Z 2 2 4 Radiation type Mo Kα Mo Kα Mo Kα μ (mm−1) 22.38 25.63 23.63 Crystal size (mm) 0.20 × 0.08 × 0.01 0.18 × 0.10 × 0.01 0.25 × 0.25 × 0.07   Data collection Diffractometer Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Absorption correction Multi-scan (CrysAlis PRO; Rigaku OD, 2020) Multi-scan (CrysAlis PRO; Rigaku OD, 2020) Multi-scan (CrysAlis PRO; Rigaku OD, 2020) Tmin, Tmax 0.140, 1.000 0.298, 1.000 0.212, 1.000 No. of measured, independent and observed [I > 2σ(I)] reflections 6279, 6279, 5020 41754, 3555, 3064 33591, 3759, 3574 Rint 0.104 0.075 0.066 θ values (°) θmax = 28.3, θmin = 2.2 θmax = 30.9, θmin = 2.4 θmax = 30.0, θmin = 2.5 (sin θ/λ)max (Å−1) 0.667 0.722 0.704   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.038, 0.063, 0.94 0.034, 0.092, 1.08 0.024, 0.040, 1.04 No. of reflections 6279 3555 3759 No. of parameters 222 117 125 No. of restraints 84 0 0 H-atom treatment H-atom parameters constrained 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) 2.43, −1.74 2.05, −1.97 1.67, −1.19 Absolute structure – – Flack x determined using 1420 quotients [(I+)−(I−)]/[(I+)+(I−)] (Parsons et al., 2013) Absolute structure parameter – – −0.024 (6) Computer programs: CrysAlis PRO (Rigaku OD, 2020), SHELXS97 (Sheldrick, 2008), SHELXL2019/3 (Sheldrick, 2015), XP (Bruker, 1998) and publCIF (Westrip, 2010).

Exceptions and special features

Compound 1: The crystal was a non-merohedral twin (by 180° rotation about the b axis). The structure was refined using the ‘HKLF 5’ method. The scale factor (relative volume of the second twinning component) refined to 0.1823 (7). The twin data reduction merges equivalent reflections, so that R_int is meaningless. The intensity dataset comprised all non-overlapped reflections from the major component and all overlapped reflections, so that the number of reflections should be inter­preted with caution. The NH hydrogen atoms were refined freely but with N—H distances restrained to be approximately equal (‘SADI’).

Compound 2: The structure was a non-merohedral twin (by 180° rotation about the vector b* + c*). The structure was refined using the ‘HKLF 5’ method. Although the relative volume of the smaller component was only 0.0400 (5), the results were significantly improved compared to a non-twin refinement. The twin data reduction merges equivalent reflections, so that R_int is meaningless. The intensity dataset comprised all non-overlapped reflections from the major component and all overlapped reflections, so that the number of reflections should be inter­preted with caution. The atoms of the second picolinium cation were disordered, and the two positions were refined using the restraint ‘SAME’. The atoms of the minor disorder component were refined isotropically. Appropriate constraints and restraints (‘RIGU’ for the major component, ‘SIMU’ and idealized ‘phen­yl’ ring geometry for the minor component, which had an occupation factor of only 0.184 (11)) were employed to improve refinement stability, but the dimensions of disordered groups should always be inter­preted with caution. In the discussion, only the major disorder position is presented. The low goodness-of-fit is probably attributable to the weak data. The low completeness (96%) is probably caused by the ‘remove outliers’ option employed during the data reduction. The NH hydrogen atoms were refined using a riding model with N—H 0.88 Å and U(H) fixed at 1.2 × U_eq of the parent nitro­gen atoms.

Compound 3: The NH hydrogen atoms were refined freely but with N—H distances restrained to be approximately equal (‘SADI’).

Compounds 4 and 6: The NH hydrogen atoms were refined freely.

Compound 5: The crystal was a non-merohedral twin by 180° rotation about the b axis. The structure was refined using the ‘HKLF 5’ method. The scale factor (relative volume of the second twinning component) refined to 0.4557 (6). The detwinning routines merge equivalent reflections, so that R_int is meaningless. The intensity dataset comprised all non-overlapped reflections from both components and all overlapped reflections, so that the number of reflections should be inter­preted with caution. For some unexplained reason, the U values of the anion and cation are unusually low, which led to problems in refining the light atoms anisotropically; U values of the cation C and N atoms were restrained to be approximately isotropic (thus avoiding NPD atoms) using the command ‘ISOR’. The solvent mol­ecule is badly resolved and has high U values, but no disorder model could be developed (and the occupation factor, when freely refined, had a value close to 1). It was refined isotropically. A referee has correctly commented that the ‘ISOR’ restraint is quite harsh, so that an isotropic refinement of the light atoms might be better. This is a moot point; our final decisions to refine the solvent isotropically and the cation C and N atoms anisotropically with restraints are clearly to some extent subjective.

Compound 7: The NH hydrogen atom was refined freely. Slow convergence of the methyl hydrogen atoms at C18 may indicate some rotational disorder of this group. The compound is achiral and crystallizes only by chance in a Sohncke space group. An extinction correction was applied, whereby the extinction coefficient, as implemented in SHELXL2019 (Sheldrick, 2015), refined to 0.00101 (7).