1. Chemical context

Some years ago, in Part 3 of this series (Taouss et al., 2015), we investigated the oxidation of the phosphane chalcogenide gold(I) complexes Ph₃PEAuX (E = S or Se, X = Cl or Br) with iodo­benzene dichloride PhICl₂ (as a more controllable substitute for elemental chlorine) or elemental bromine. We were expecting to obtain the corresponding Ph₃PEAuX₃ complexes, and these were indeed formed, but excess halogen led to the unexpected doubly oxidized ionic products [Ph₃PEX][AuX₄] (for E = S, X = Cl and Br and E = Se, X = Br), involving halochalcogenyl­phospho­nium cations, previously unknown for X = Cl or Br (but known for X = I; du Mont et al. (2008) and references therein). The combination E = Se, X = Cl led instead to [Ph₃PSeCl]₂[Au₄Se₂Cl₁₀]. We also obtained one structure of a similar compound with [2.2]para­cyclo­phanyldiiso­propyl­phosphane and E = Se, X = Cl (Upmann et al., 2019).

We then extended our studies to phosphane chalcogenides involving alkyl groups. In Part 6 of this series (Upmann et al., 2024a) we presented the structures of sixteen halogenido-gold(I) complexes of various tri­alkyl­phosphane chalcogenides, and in Part 7 (Upmann et al., 2024b) the structures of ten corresponding trihalogenido-gold(III) complexes. Further background material, including a more extensive summary of our previous results, can be found in Part 6 and is not repeated here.

In this paper, we report the structures of fourteen (halochalcogenyl)tri­alkyl­phospho­nium tetra­halogenido­aurates(III) of general formula [^tBu_3–nⁱPr_nPEX][AuX₄]. In total there are sixteen possible permutations of n (0–3), the chalcogenide E (S or Se) and the halogen X (Cl or Br), but the two compounds with n = 0 and E = Se were not obtained. The chlorine derivatives are numbered 17a–23a and the bromine derivatives 17b–23b, following on from the gold(I) complexes 1–8 and the gold(III) complexes 9–16 in the previous papers (Upmann et al., 2024a,b). Details of the composition of each compound studied are given in Table 1. The structures of 18a, 19a, 22a and 23a were briefly presented in a preliminary communication (Upmann & Jones, 2013), but have been re-refined using a much more recent version of SHELXL (2019 rather than 1997; Sheldrick, 2015) and are discussed in more detail here. We abstain from giving the systematic names for all these compounds; compound 21a, for instance, is (chloro­selan­yl)triiso­propyl­phospho­nium tetra­chlorido­aurate(III), 18b is (bromo­sulfanyl)(tert-but­yl)diiso­propyl­phospho­nium tetra­chlorido­aurate(III), and the others may be named analogously.

2. Structural commentary

General comments: All compounds crystallized solvent-free and with Z′ = 1 (although all structures except 17a contain two independent [AuX₄]⁻ anions, each with crystallographic symmetry). The mol­ecular structures are shown in Figs. 1–14, with selected bond lengths and angles in Tables 2–15.

Figure 1 The structure of compound 17a in the crystal. Ellipsoids represent 30% probability levels.

Figure 2 The structure of compound 18a in the crystal. Ellipsoids represent 50% probability levels.

Figure 3 The structure of compound 19a in the crystal. Ellipsoids represent 50% probability levels. Only one position of the disordered atoms Cl3 and Cl4 is shown.

Figure 4 The structure of compound 20a in the crystal. Ellipsoids represent 50% probability levels.

Figure 5 The structure of compound 21a in the crystal. Ellipsoids represent 50% probability levels.

Figure 6 The structure of compound 22a in the crystal. Ellipsoids represent 50% probability levels.

Figure 7 The structure of compound 23a in the crystal. Ellipsoids represent 50% probability levels. Only one position of the disordered atoms Cl3 and Cl4 is shown.

Figure 8 The structure of compound 17b in the crystal. Ellipsoids represent 50% probability levels.

Figure 9 The structure of compound 18b in the crystal. Ellipsoids represent 50% probability levels.

Figure 10 The structure of compound 19b in the crystal. Ellipsoids represent 50% probability levels.

Figure 11 The structure of compound 20b in the crystal. Ellipsoids represent 50% probability levels.

Figure 12 The structure of compound 21b in the crystal. Ellipsoids represent 50% probability levels.

Figure 13 The structure of compound 22b in the crystal. Ellipsoids represent 50% probability levels.

Figure 14 The structure of compound 23c in the crystal. Ellipsoids represent 50% probability levels.

Isotypy: The four structures 18a, 22a, 18b and 22b form an isotypic set; the pairs 19a/23a, 17b/21b, and 19b/23b are also isotypic. Within each set of isotypic structures, the n value is the same.

Bond lengths and angles (1). [AuX₄]⁻ anions: For 17a, the anion lies on a general position. For 19a and 23a, Au1 lies on a twofold axis and Au2 on an inversion centre, and the chlorine atoms at Au1 are disordered (with the atoms Cl3 and Cl4 being slightly displaced from the ideal positions on the twofold axis). All other anions lie with the gold atoms on inversion centres. The local symmetry approximates closely to the ideal 4/mmm, and there are no clear trends in the influence of the short X⋯X contacts on the Au—X bond lengths (see Supra­molecular features).

Bond lengths and angles (2). (Halochalcogenyl)tri­alkyl­phospho­nium cations: The P—S bond lengths lie in the range 2.0852–2.1035 Å, av. 2.0952 Å; the P—Se bond lengths are 2.2364–2.2557 Å, av. 2.2477 Å. These averages are slightly larger than in the trihalogenido-gold(III) complexes (2.0602 and 2.2183 Å), and may reasonably be regarded as corresponding to essentially single P—E bonds (for the mild controversy about the P—E bond order in phosphane chalcogenides, see e.g. Schmøkel et al., 2012). The E—X bond lengths are: S—Cl = 2.023–2.0316 Å, av. 2.0291 Å; Se—Cl = 2.1645–2.1736 Å, av. 2.1678 Å; S—Br = 2.1934–2.2077 Å, av. 2.2004 Å; Se—Br = 2.3179–2.3255 Å, av. 2.3224 Å. For CCDC results on related bond lengths, see the Database survey below.

For each group of P—E—X bond angles, the values increase monotonically (with one extremely slight exception) with the steric bulk of the alkyl groups (P—S—Cl = 99.25–104.74°, P—Se—Cl = 98.38–100.40°, P—S—Br = 99.46–105.70°, P—Se—Br = 96.32–101.91°). For analogous S/Se pairs, the angles at Se are consistently smaller than those at S. For each cation, one of the alkyl groups (always a t-butyl group, if present) lies approximately anti­periplanar (‘trans’) to X in the atom sequence C—P—E—X; the central carbon atom of this group is consistently labelled C1. This behaviour, for which we see no clear explanation, contrasts with that of the gold(I) derivatives in Part 6, where the isopropyl group (where present, with two exceptions) occupied the trans position, and also with that of the gold(III) derivatives in Part 7, where the tendency of the isopropyl group to lie trans to X was overridden in all the ^tBu₂ⁱPrPE derivatives; we inter­preted this in terms of a greater importance of intra­molecular hydrogen bonds C—H_methine⋯X. Selected dimensions of previously published halochalcogenyl­phospho­nium cations are shown in Table 16. There are some differences, e.g. the somewhat shorter Se—Cl bonds in this paper compared to the previous values, for which we also see no obvious explanation.

Table 16 Selected dimensions (Å, °) of published structures of halochalcogenyl­phospho­nium cations Compound P—E E—X P—E—X Reference [Ph3PSCl][AuCl4] 2.0912 (12) 2.2278 (13) 99.87 (5) Taouss et al. (2015) [Ph3PSBr][AuBr4] 2.0854 (16) 2.2023 (14) 101.31 (6) Taouss et al. (2015) [Ph3PSeBr][AuBr4] 2.2250 (7) 2.3121 (4) 97.10 (2) Taouss et al. (2015) [Ph3PSeCl]2[Au4Se2Cl10] 2.216 (2) 2.222 (3) 96.83 (9) Taouss et al. (2015) [(PCP)iPr2PSeCl][AuCl4]a 2.257 (2) 2.207 (2) 94.69 (9) Upmann et al. (2019) Note: (a) PCP = [2.2]para­cyclo­phanyl.

Contacts between the anion and cation of the asymmetric unit, as shown in Figs. 1–14, are discussed in the next section.

3. Supra­molecular features

For general aspects of packing and types of secondary inter­action, as applied to these compounds, a series of general articles are cited in our previous paper (Upmann et al., 2024a). Details of contacts are given in Tables 16–18, while hydrogen bonds are given in Tables 19–32; these include intra­molecular contacts (see above) and several borderline cases, and not all of them will be discussed. The corresponding symmetry operators, not given explicitly in the following discussion, may also be found in those Tables. In all packing diagrams presented here, hydrogen atoms not involved in hydrogen bonding are omitted for clarity, and the atom labels indicate the asymmetric unit. It is worth repeating the caveat that X-ray methods reveal short inter­molecular contacts, but not the corresponding energies, so that descriptions of mol­ecular packing in terms of particular secondary contacts must to some extent be subjective. Furthermore, there is no clear objective judgement, on the basis of contact lengths and angles, as to which contacts should be regarded as more important or less important for the packing. Finally, the exposed nature of the one-coordinate halogen atoms, taken together with the large number of hydrogen atoms, means that some short H⋯X contacts are inevitable. Nevertheless, it is possible to provide informative packing diagrams.

Table 18 Dimensions (Å, °) of chalcogen⋯chlorine contacts between cations and anions Compound E⋯Cl P—E⋯Cl E⋯Cl—Au E⋯Cl—Au—Clcisb 17a (E = S) S1⋯Cl5 3.553 (3) 152.59 (11) 109.61 (7) 26.54 (8) 19a (E = S)a S1⋯Cl2 3.3240 (17) 162.69 (7) 95.10 (4) 61.7 (2) 23a (E = Se)a Se1⋯Cl2 3.3052 (6) 164.50 (2) 95.40 (6) 59.37 (2) [Ph3PSeCl]2[Au4Se2Cl10]c Se1⋯Cl6 3.308 (3) 158.99 (9) 116.86 (9) 55.06 (10) Notes: (a) Compounds 19a and 23a are isotypic. In both structures, the cis chlorines are disordered. (b) The smaller absolute torsion angle (of two) is shown; the value to the other Clcis is the complementary angle (exactly or approximately, depending on the symmetry) with the opposite sign. (c) Upmann et al. (2019).

Table 19 Hydrogen-bond geometry (Å, °) for 17a D—H⋯A D—H H⋯A D⋯A D—H⋯A C2—H2⋯Cl1 1.00 2.86 3.343 (7) 110 C32—H32C⋯Cl1 0.98 2.83 3.527 (7) 129 C12—H12B⋯S1 0.98 2.57 3.069 (9) 111 C21—H21B⋯S1 0.98 2.88 3.415 (8) 115 C22—H22C⋯Cl3i 0.98 2.89 3.843 (7) 164 C1—H1⋯Cl4i 1.00 2.83 3.721 (7) 149 C32—H32A⋯Cl4ii 0.98 2.88 3.731 (7) 145 C3—H3⋯Cl5ii 1.00 2.72 3.701 (7) 167 Symmetry codes: (i) ; (ii) .

Table 20 Hydrogen-bond geometry (Å, °) for 18a D—H⋯A D—H H⋯A D⋯A D—H⋯A C13—H13B⋯S1 0.98 2.63 3.073 (2) 107 C2—H2⋯Cl1 1.00 2.95 3.383 (2) 107 C32—H32C⋯Cl1 0.98 2.90 3.635 (2) 133 C21—H21C⋯Cl3 0.98 2.93 3.705 (2) 137 C11—H11A⋯Cl5 0.98 2.97 3.742 (2) 136 C3—H3⋯Au2 1.00 2.75 3.693 (2) 158 C2—H2⋯Cl2i 1.00 2.93 3.688 (2) 133 C22—H22A⋯Cl3ii 0.98 2.82 3.642 (2) 142 C12—H12B⋯Cl3iii 0.98 2.91 3.754 (2) 145 C13—H13B⋯Cl3iii 0.98 2.98 3.876 (2) 153 C12—H12A⋯Cl4iv 0.98 2.78 3.699 (2) 157 C13—H13A⋯Cl4v 0.98 2.93 3.760 (2) 143 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) ; (v) .

Table 21 Hydrogen-bond geometry (Å, °) for 19a D—H⋯A D—H H⋯A D⋯A D—H⋯A C3—H3⋯Au2 1.00 2.93 3.786 (5) 144 C3—H3⋯Cl6 1.00 2.90 3.751 (5) 143 C13—H13A⋯S1 0.98 2.46 3.049 (5) 118 C23—H23B⋯Cl1 0.98 2.74 3.305 (5) 117 C31—H31B⋯Cl1 0.98 2.66 3.393 (5) 132 C23—H23A⋯Cl6i 0.98 2.74 3.713 (5) 173 C21—H21C⋯Cl6ii 0.98 2.90 3.672 (5) 137 C13—H13B⋯Cl3iii 0.98 2.81 3.536 (8) 131 C22—H22B⋯Cl2iv 0.98 2.87 3.783 (5) 156 C13—H13C⋯Cl4v 0.98 2.89 3.677 (19) 138 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) ; (v) .

Table 22 Hydrogen-bond geometry (Å, °) for 20a D—H⋯A D—H H⋯A D⋯A D—H⋯A C23—H23B⋯Cl1 0.98 2.71 3.522 (4) 141 C22—H22B⋯Cl1 0.98 2.68 3.497 (4) 141 C33—H33B⋯Cl1 0.98 2.82 3.401 (4) 118 C13—H13A⋯Cl5i 0.98 2.88 3.796 (4) 156 C12—H12C⋯Cl5 0.98 2.92 3.810 (4) 151 C31—H31C⋯Cl5ii 0.98 2.84 3.763 (4) 158 C12—H12C⋯S1 0.98 2.44 3.027 (4) 118 C22—H22B⋯S1 0.98 2.92 3.370 (4) 109 C33—H33B⋯S1 0.98 2.92 3.424 (4) 113 C21—H21A⋯Cl4iii 0.98 2.77 3.708 (4) 161 Symmetry codes: (i) ; (ii) ; (iii) .

Table 23 Hydrogen-bond geometry (Å, °) for 21a D—H⋯A D—H H⋯A D⋯A D—H⋯A C21—H21B⋯Cl1 0.98 2.84 3.545 (2) 129 C32—H32C⋯Cl1 0.98 2.95 3.712 (2) 135 C1—H1⋯Cl5 1.00 2.93 3.8615 (19) 156 C2—H2⋯Cl2i 1.00 2.82 3.6147 (19) 137 C3—H3⋯Cl2ii 1.00 2.94 3.5249 (19) 118 C31—H31C⋯Cl2ii 0.98 2.98 3.626 (2) 125 C21—H21C⋯Cl2iii 0.98 2.98 3.868 (2) 151 C11—H11C⋯Cl4iii 0.98 2.87 3.828 (2) 166 C1—H1⋯Cl4iv 1.00 2.78 3.5341 (19) 133 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) .

Table 24 Hydrogen-bond geometry (Å, °) for 22a D—H⋯A D—H H⋯A D⋯A D—H⋯A C13—H13B⋯Se1 0.98 2.65 3.142 (3) 111 C2—H2⋯Cl1 1.00 2.99 3.454 (3) 110 C3—H3⋯Au2 1.00 2.75 3.690 (3) 157 C32—H32C⋯Cl1 0.98 2.92 3.682 (3) 135 C21—H21C⋯Cl3 0.98 2.99 3.774 (3) 138 C11—H11A⋯Cl5 0.98 2.97 3.741 (3) 137 C2—H2⋯Cl2i 1.00 2.87 3.629 (3) 133 C22—H22A⋯Cl3ii 0.98 2.79 3.629 (3) 144 C12—H12B⋯Cl3iii 0.98 2.95 3.783 (3) 143 C13—H13B⋯Cl3iii 0.98 3.01 3.902 (3) 152 C12—H12A⋯Cl4iv 0.98 2.80 3.721 (3) 156 C13—H13A⋯Cl4v 0.98 2.94 3.751 (3) 141 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) ; (v) .

Table 25 Hydrogen-bond geometry (Å, °) for 23a D—H⋯A D—H H⋯A D⋯A D—H⋯A C3—H3⋯Au2 1.00 2.95 3.805 (2) 144 C3—H3⋯Cl6 1.00 2.88 3.730 (2) 143 C13—H13A⋯Se1 0.98 2.52 3.110 (3) 119 C23—H23B⋯Cl1 0.98 2.81 3.385 (3) 118 C31—H31B⋯Cl1 0.98 2.66 3.451 (3) 138 C23—H23A⋯Cl6i 0.98 2.76 3.736 (2) 173 C21—H21C⋯Cl6ii 0.98 2.90 3.674 (2) 137 C13—H13B⋯Cl3iii 0.98 2.80 3.498 (4) 129 C22—H22B⋯Cl2iv 0.98 2.86 3.787 (3) 157 C13—H13C⋯Cl4v 0.98 2.85 3.685 (15) 143 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) ; (v) .

Table 26 Hydrogen-bond geometry (Å, °) for 17b D—H⋯A D—H H⋯A D⋯A D—H⋯A C21—H21B⋯Br1 0.98 3.28 3.864 (3) 120 C3—H3⋯Br2i 1.00 3.29 3.792 (3) 113 C31—H31C⋯Br2i 0.98 3.00 3.787 (3) 138 C32—H32A⋯Br2i 0.98 2.98 3.763 (3) 137 C1—H1⋯Br4i 1.00 3.15 3.997 (3) 144 C21—H21C⋯Br4ii 0.98 3.06 3.943 (3) 151 C31—H31B⋯Br4i 0.98 3.04 3.983 (3) 162 C1—H1⋯Br5i 1.00 2.98 3.802 (3) 140 C22—H22C⋯Br5iii 0.98 3.11 3.911 (3) 140 Symmetry codes: (i) ; (ii) ; (iii) .

Table 27 Hydrogen-bond geometry (Å, °) for 18b D—H⋯A D—H H⋯A D⋯A D—H⋯A C13—H13B⋯S1 0.98 2.66 3.095 (4) 107 C2—H2⋯Br1 1.00 2.99 3.459 (4) 110 C3—H3⋯Au2 1.00 2.89 3.828 (4) 156 C32—H32C⋯Br1 0.98 3.01 3.739 (4) 132 C21—H21C⋯Br3 0.98 2.98 3.814 (4) 143 C11—H11A⋯Br5 0.98 3.07 3.778 (4) 130 C2—H2⋯Br2i 1.00 3.28 4.017 (4) 132 C22—H22A⋯Br3ii 0.98 2.95 3.771 (4) 142 C12—H12B⋯Br3iii 0.98 2.93 3.832 (4) 154 C13—H13B⋯Br3iii 0.98 3.18 4.075 (4) 152 C12—H12A⋯Br4iv 0.98 2.80 3.747 (4) 163 C13—H13A⋯Br4v 0.98 3.07 3.776 (4) 130 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) ; (v) .

Table 28 Hydrogen-bond geometry (Å, °) for 19b D—H⋯A D—H H⋯A D⋯A D—H⋯A C13—H13A⋯S1 0.98 2.59 3.089 (5) 112 C31—H31B⋯Br1 0.98 2.72 3.487 (5) 135 C23—H23B⋯Br1 0.98 2.91 3.407 (6) 112 C3—H3⋯Br3 1.00 3.04 4.007 (5) 164 C23—H23C⋯Br3 0.98 3.09 4.040 (5) 165 C11—H11C⋯Br4 0.98 3.11 4.084 (5) 171 C31—H31C⋯Br2i 0.98 3.06 3.781 (5) 132 C23—H23A⋯Br4ii 0.98 2.90 3.824 (5) 157 C13—H13C⋯Br4iii 0.98 3.08 4.024 (5) 162 C32—H32C⋯Br4i 0.98 3.03 3.814 (5) 138 C11—H11A⋯Br5iii 0.98 3.06 3.846 (5) 138 C32—H32C⋯Br5iv 0.98 3.00 3.864 (5) 148 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) .

Table 29 Hydrogen-bond geometry (Å, °) for 20b D—H⋯A D—H H⋯A D⋯A D—H⋯A C12—H12C⋯S1 0.98 2.53 3.036 (5) 112 C22—H22B⋯Br1 0.98 2.74 3.569 (5) 143 C23—H23A⋯Br1 0.98 2.80 3.617 (5) 142 C22—H22A⋯Br2i 0.98 2.97 3.739 (5) 137 C13—H13C⋯Br4ii 0.98 2.95 3.859 (5) 154 C21—H21A⋯Br4iii 0.98 2.85 3.785 (5) 160 Symmetry codes: (i) ; (ii) ; (iii) .

Table 30 Hydrogen-bond geometry (Å, °) for 21b D—H⋯A D—H H⋯A D⋯A D—H⋯A C21—H21B⋯Br1 0.98 3.34 3.927 (4) 120 C3—H3⋯Br2i 1.00 3.27 3.788 (3) 114 C31—H31C⋯Br2i 0.98 3.08 3.836 (3) 135 C32—H32A⋯Br2i 0.98 2.96 3.740 (3) 137 C1—H1⋯Br4i 1.00 3.18 4.045 (3) 145 C21—H21C⋯Br4ii 0.98 3.08 3.953 (3) 149 C31—H31B⋯Br4i 0.98 3.03 3.972 (4) 162 C1—H1⋯Br5i 1.00 2.93 3.756 (4) 140 C22—H22C⋯Br5iii 0.98 3.15 3.893 (4) 134 Symmetry codes: (i) ; (ii) ; (iii) .

Table 31 Hydrogen-bond geometry (Å, °) for 22b D—H⋯A D—H H⋯A D⋯A D—H⋯A C13—H13B⋯Se1 0.98 2.70 3.167 (4) 109 C2—H2⋯Br1 1.00 3.05 3.540 (4) 112 C3—H3⋯Au2 1.00 2.85 3.783 (4) 155 C32—H32C⋯Br1 0.98 3.05 3.788 (4) 134 C21—H21C⋯Br3 0.98 3.03 3.848 (4) 142 C11—H11A⋯Br5 0.98 3.05 3.787 (4) 133 C2—H2⋯Br2i 1.00 3.17 3.901 (4) 131 C22—H22A⋯Br3ii 0.98 2.92 3.764 (4) 144 C12—H12B⋯Br3iii 0.98 2.96 3.826 (4) 148 C13—H13B⋯Br3iii 0.98 3.15 4.051 (4) 153 C12—H12A⋯Br4iv 0.98 2.82 3.761 (4) 160 C13—H13A⋯Br4v 0.98 3.05 3.771 (5) 132 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) ; (v) .

Table 32 Hydrogen-bond geometry (Å, °) for 23b D—H⋯A D—H H⋯A D⋯A D—H⋯A C13—H13A⋯Se1 0.98 2.60 3.163 (8) 116 C31—H31B⋯Br1 0.98 2.78 3.551 (7) 137 C23—H23B⋯Br1 0.98 2.98 3.476 (8) 112 C3—H3⋯Br3 1.00 3.13 4.108 (7) 166 C23—H23C⋯Br3 0.98 3.05 3.994 (9) 161 C11—H11C⋯Br4 0.98 3.23 4.182 (7) 165 C31—H31C⋯Br2i 0.98 3.06 3.825 (7) 136 C23—H23A⋯Br4ii 0.98 2.91 3.824 (7) 156 C13—H13C⋯Br4iii 0.98 3.06 3.998 (8) 160 C32—H32C⋯Br4i 0.98 3.01 3.782 (7) 136 C11—H11A⋯Br5iii 0.98 3.12 3.874 (7) 135 C32—H32C⋯Br5iv 0.98 2.93 3.804 (8) 149 Symmetry codes: (i) ; (ii) ; (iii) ; (iv) .

The most striking secondary inter­actions are the short halogen⋯halogen contacts between cation and anion; these are shown explicitly in Figs. 1–14 (except for compounds 17a, 19a and 23a, for which instead chalcogen⋯halogen contacts are observed; see below). From our previous experiences, we expected this type of inter­action to be ubiquitous for these compounds, but this proved to be an erroneous assumption; only eleven of the fourteen structures display such X⋯X contacts, and we discuss these first. Selected contact dimensions are given in Table 17. The common features (exceptions are discussed below) are: (1) The X⋯X distance is generally shorter than the double van der Waals radius and in some cases extremely short, e.g. the Br⋯Br distance of 3.1509 (7) Å in [Ph₃PSBr][AuBr₄]. Being ‘softer’ than chlorine, bromine would be expected to form stronger (and thus shorter compared to the van der Waals distance) contacts. (2) The E—X⋯X grouping is approximately linear. (3) The X⋯X—Au angle is approximately 90°. (4) The relative orientation of the anion and cation is described by the torsion angle X⋯X—Au—X_cis; this too is approximately 90° (positive for one X_cis and negative for the other).

The combination of linear E—X⋯X and right-angled X⋯X—Au parallels the model for short contacts C—X⋯X—C in organic compounds, and both may be regarded as a form of ‘halogen bonding’ (see e.g. Metrangolo et al., 2008). The strongest C—X⋯X—C inter­actions are termed ‘type II’ according to the classification of Pedireddi et al. (1994) and are characterized by C—X⋯X angles of approximately 180 and 90°. The simple model is that (as shown by calculation) there is a small region of positive charge δ+ in the direction extending one C—X vector, while the overall δ- charge of the other X atom (because of its higher electronegativity compared to carbon) is distributed perpendicular to the C—X bond (Legon, 2010). We are, however, not aware of similar calculations for atoms other than carbon.

The main exceptions to the above generalities involve the tri-t-butyl derivatives 20a and 20b, which show the narrowest E—X⋯X angles [159.83 (6) and 157.33 (4)°], the widest X⋯X—Au angles [115.19 (4) and 112.62 (2)°] and completely different absolute torsion angles X⋯X—Au—X_cis of 8.88 (5) and 9.80 (2)° [paired with 171.12 (2) and 170.20 (2)° for the other X_cis atom], so that these four atoms form a synperiplanar grouping. The compound [Ph₃PSeBr][AuBr₄] is also an outlier, with X⋯X—Au—X_cis values of 48.32 (1) and −131.68 (1)°.

The other three structures (17a, 19a and 23a) involve E⋯Cl contacts between the cation and the anion, as we had previously observed for [Ph₃PSeCl]₂[Au₄Se₂Cl₁₀] (Upmann et al., 2019), rather than halogen⋯halogen contacts. Details are given in Table 18. The P—E⋯Cl angles are approximately linear and the E⋯Cl—Au angles are somewhat larger than right angles, but there are no clear trends for the torsion angles E⋯Cl—Au—Cl_cis. Since the E atoms presumably carry a partial positive charge, and the Cl atoms a partial negative charge, these E⋯Cl contacts may be termed as ‘chalcogen bonds’, a class of secondary contact named in analogy to ‘halogen bonds’. Other criteria also fulfil the requirements given by Aakeroy et al. (2019). The topic of chalcogen bonds has been reviewed by Vogel et al. (2019).

Of course other types of inter­molecular contact are also involved in the overall packing, which we now describe. The decision as to which contacts are more or less important is, as remarked above, to some extent subjective; a packing pattern is more assimilable to the human eye if it involves a small number of contacts, and we have tended to choose heavy-atom contacts rather than possible hydrogen bonds. Where the latter are considered, we tend to concentrate on the inter­actions of the methine rather than the methyl hydrogens; we established in the series of R¹R²R³PEAuX₃ complexes that the methine hydrogen atoms have a greater tendency than methyl hydrogens to form ‘weak’ hydrogen bonds, thereby influencing the mol­ecular conformation by forming intra­molecular H⋯X hydrogen bonds.

Dance (2003) has pointed out (our paraphrasing) that packing energies are probably determined in many cases by a large number of slightly favourable inter­actions, such as H⋯H van der Waals contacts, rather than a small number of very short contacts (of which the shortest may even be unfav­ourable in energy terms). Despite this, it is probably inevit­able that one will (over)emphasize the contacts between heavy atoms in order to make the diagrams more inter­pretable. Packing diagrams based on the extremely numerous weakly attractive H⋯H inter­actions would be neither easily drawn nor easily inter­preted.

For compound 17a, the S⋯Cl inter­action combines with two hydrogen bonds from the methine hydrogens H1 and H3 to form a layer structure parallel to (01) (Fig. 15). The atom H2 makes a short intra­cationic contact to Cl1, but the angle is necessarily very narrow.

Figure 15 Packing diagram of 17a. Two H⋯Cl contacts combine with the S⋯Cl inter­actions to form a layer structure parallel to (01); the viewing direction is perpendicular to this plane. The dashed lines indicate S⋯Cl inter­actions (thick) or H⋯Cl contacts (thin). For all packing diagrams, atom labels correspond to the asymmetric unit, and hydrogen atoms not involved in hydrogen bonds are omitted for clarity.

The packing of compound 18a may be described in terms of three secondary inter­actions: the short Cl1⋯Cl2 contact, an unusually short contact C3—H3⋯Au2 (H⋯Au = 2.75 Å) that could be classified as a hydrogen bond (Schmidbaur et al., 2014 and Schmidbaur, 2019) and another strikingly short contact, Cl5⋯Cl5(2 − x, 1 − y, −z) = 3.2632 (10) Å, between anions. The angle Au2—Cl5⋯Cl5’ is 149.86 (3)°. We have drawn attention to such short contacts between [AuX₄]⁻ anions elsewhere (Döring & Jones, 2016). The first two contacts lead to the formation of zigzag chains with overall direction parallel to [10] (Fig. 16), further linked by the contact S1⋯Cl2(−x, −y, 1 − z) = 3.5768 (8) Å; the second and third contacts link cations and Au2 anions parallel to the a axis (Fig. 17). The contact H2⋯Cl2′ between the cation and a symmetry-extended anion is rather long at 2.93 Å; it can be recognized in Fig. 2, but is not drawn explicitly there, and is not included in the packing diagram.

Figure 16 Packing diagram of 18a viewed perpendicular to (212), showing two zigzag chains of residues (running horizontally). Dashed lines indicate Cl⋯Cl and H⋯Au contacts (thick) or S⋯Cl contacts (thin).

Figure 17 Packing diagram of 18a viewed perpendicular to the xy plane in the region z ≃ 0. Dashed lines indicate Cl⋯Cl and H⋯Au contacts.

Compounds 18a, 18b, 22a and 22b, with all possible permutations of E = S/Se and X = Cl/Br, are isotypic, and so it should not be necessary to provide separate packing diagrams. However, this set of compounds provides a good opportunity to consider the definition of ‘isotypic’ and the subjectivity of packing diagrams. For 18a, we considered the S1⋯Cl2 contact to be significant, but did not include the significantly longer contact S1⋯Cl3(1 − x, −y, 1 − z), 3.7012 (8) Å, regarding it (arbitrarily) as too long. The corresponding contacts (in Å; same operator as above) for the other compounds are: 18b, S1⋯Br2 = 4.0635 (10) and S1⋯Br3 = 3.6779 (11); 22a, Se1⋯Cl2 = 3.4602 (7) and Se1⋯Cl3 = 3.7004 (8); 22b, Se1⋯Br2 = 3.7704 (6) and Se1⋯Br3 = 3.7484 (6). We draw attention to the considerable variations in the lengths of these contacts; thus S1⋯Br2 might well be ignored for 18b, while S1⋯Br3 is the shorter and thus more significant contact. For 22a, Se1⋯Cl2 is the much shorter inter­action, whereas for 22b the lengths are almost equal. For 22b, one can then draw an alternative packing diagram excluding the anion based on Au2, showing both Se⋯Br contacts (Fig. 18). The residues are linked by these contacts and by Br1⋯Br2 to provide crosslinked chains of anions and cations parallel to [10], forming a layer structure parallel to the ab plane, in which ten-membered rings Au₂Se₂Br₆ can be recognized.

Figure 18 Packing diagram of 22b viewed perpendicular to the ab plane. Hydrogen atoms and the anions based on Au2 are omitted. Residues are linked by Br⋯Br and Se⋯Br contacts (thick dashed lines) to form linear arrays (parallel to [10], horizontal in the diagram), further crosslinked to form a layer.

The potential hydrogen bond H2⋯Cl2′, ignored for 18a (as discussed above) as being ‘too long’ at 2.93 Å, also behaves somewhat differently for the other three isotypic structures: for 18b H2⋯Cl2′ is shorter at 2.87 Å, whereas for the two bromo derivatives 18b and 22b the H2⋯Br2′ contacts are very long at 3.28 and 3.17 Å, respectively. This again draws attention to possible significant differences between isotypic structures and to the arbitrary nature of decisions to include or exclude particular contacts in the discussion of the packing. During the preparation of this paper, Bombicz (2024) published a commentary ‘What is isostructurality?’, in which she raised similar questions, commenting for instance that ‘The extent of the difference between corresponding crystal structures referred to as isostructural is not limited’, and that the IUCr definition of ‘isostructural/isotypic’ (regarded as synonymous terms) is vague on this point.

Compound 19a and the isotypic 23a (as discussed above, see Figs. 3 and 7) involve E⋯Cl rather than Cl⋯Cl inter­actions between the cation and one anion (based on Au1); the other anion (based on Au2) is close to the methine hydrogen H3, with H3⋯Au2 and H3⋯Cl6 distances of 2.93, 2.90 Å for 19a and 2.95, 2.88 Å for 23a that might be inter­preted as three-centre hydrogen bonds. The main feature of the packing (as shown in Fig. 19 for 23a) is the formation of almost square networks of [AuCl₄]⁻ anions, involving Au1, parallel to the bc plane in the regions x ≃ 0, 0.5, within which the cations are linked via E⋯Cl contacts. The contact distances (Å) are S1⋯Cl4(1 − x, y,  − z) = 3.80, Cl3⋯Cl4(x, 1 + y, z) = 3.30, Cl2⋯Cl2(1 − x, 2 − y, 1 − z) = 3.633 (2) for 19a and Se1⋯Cl4 = 3.77, Cl3⋯Cl4 = 3.28, Cl2⋯Cl2 = 3.6717 (12) for 23a (note however that the disorder of Cl3 and Cl4 make these values uncertain; in Fig. 19, the idealized positions on the twofold axis are used for clarity, and these are the basis for the calculated distances). The [AuCl₄]⁻ anions involving Au2 occupy the regions at x ≃ 0.25, 0.75.

Figure 19 Packing diagram of 23a viewed perpendicular to the bc plane in the region x ≃ 0.5. Hydrogen atoms and the anion based on Au2 are omitted. For clarity, the positions of the disordered atoms Cl3 and Cl4 are idealized to lie on the twofold axes. Thick dashed lines indicate Cl⋯Cl or Se⋯Cl contacts.

Compound 20a forms winding chains parallel to the c axis (Fig. 20); residues are linked by the inter­ionic Cl1⋯Cl2 contact and a double contact from S1 to two chlorine atoms of a neighbouring anion [S1⋯Cl4 = 3.6661 (14), S1⋯Cl5 = 3.5471 (14) Å], whereby the corresponding S1⋯Au2 distance is necessarily short at 3.7113 (9) Å. Chains are linked by several H⋯Cl contacts.

Figure 20 Packing diagram of 20a. The viewing direction has been rotated by ca 20° and 10° respectively around the horizontal and vertical directions from the direction parallel to the b axis (to avoid overlap of the two S⋯Cl contacts). Hydrogen atoms are omitted for clarity. Dashed lines indicate Cl⋯Cl and S⋯Cl contacts. The unusual orientation of the tetra­chloro­aurate(III) anion at Au1, with an approximately synperiplanar grouping Cl1⋯Cl2—Au1—Cl3, can be recognized.

In the packing of compound 21a, two Se⋯Cl contacts [Se1⋯Cl5 = 3.3504 (6) and Se1⋯Cl5(2 − x, 1 − y, 1 − z) = 3.3728 (5) Å], which form striking Se₂Cl₂ quadrilaterals, combine with the long Cl1⋯Cl2 contact, 3.6031 (7) Å, and two H_methine⋯Cl hydrogen bonds to symmetry-extended anions to form a layer structure parallel to (10) (Fig. 21). The quadrilaterals are thereby linked directly by [AuCl₄]⁻ anions involving Au2, parallel to the b axis, and indirectly via [AuCl₄]⁻ anions involving Au1, parallel to [111]. The methine hydrogen H1 makes a short contact to Cl4′ (2.78 Å), but also a longer contact of 2.93 Å to the neighbouring Cl5 atom; this may be regarded as an asymmetric three-centre system, but the longer contact is omitted from the Figures. The third methine hydrogen, H3, also makes a longer contact of 2.94 Å to Cl2(x, 1 + y, z); this contact also lies in the layer but is omitted for clarity.

Figure 21 Packing diagram of 21a, viewed perpendicular to (10). Dashed lines indicate Cl⋯Cl and Se⋯Cl contacts (thick) or Hmethine⋯Cl hydrogen bonds (thin). Note that the set of AuCl4− anions based on Au2 is seen edge on, whereby the gold atoms are obscured.

The packing of 17b only has one strikingly short contact, Br1⋯Br2 = 3.3206 (5) Å between anion and cation, but there is also a three-centre grouping with Br4⋯Br1 = 3.8725 (5) and Br4⋯S1 = 3.7666 (8) Å, also within the asymmetric unit. Additionally, the borderline contacts Br1⋯Br2(2 − x, 1 − y, −z) = 3.8652 (5), Br3⋯Br4(−1 + x, y, z) = 3.8725 (5) and Br5⋯Br5(2 − x, −1 − y, 1 − z) = 3.8808 (6) Å link the residues to form layers parallel to the ab plane (Fig. 22). The two possible weak hydrogen bonds H1⋯Br5 and H3⋯Br3, quite long but reasonably linear, also lie within these layers, but are omitted from Fig. 22 for clarity. The isotypic structure 21b has a much shorter corresponding Se1⋯Br4 contact of 3.6501 (5) Å.

Figure 22 Layer structure of 17b viewed perpendicular to the ab plane in the region z ≃ 0.25. Dashed lines indicate contacts S1⋯Br4 and Br1⋯Br2 (thick) or other appreciably longer Br⋯Br contacts (thin).

For compound 19b, there are two very short Br⋯Br contacts, namely Br1⋯Br2 = 3.2686 (7) Å between cation and anion and Br3⋯Br5( + x,  − y,  + z) = 3.3324 (6) Å between the two anions. These are accompanied by the three-centre association of S1⋯Br4 = 3.7797 (13) and S1⋯Br5 = 3.6326 (12) Å and the probable hydrogen bond H3⋯Br3 (Fig. 10), all within the asymmetric unit, to form a layer structure parallel to (10) (Fig. 23). The corresponding distances for the isotypic 23b are Br1⋯Br2 = 3.3416 (11), Br3⋯Br5 = 3.3205 (10), Se1⋯Br4 = 3.8310 (11) and Se1⋯Br5 = 3.5473 (10) Å.

Figure 23 Layer structure of 19b viewed perpendicular to (10). Dashed lines indicate short Br⋯Br contacts (thick) or rather longer S⋯Br contacts (thin). The anions based on Au2 are viewed edge-on, so that the atom Au2 is obscured by Br4. The corresponding anion at the right-hand edge of the cell is shown more clearly. The probable hydrogen bonds H3⋯Br3 (see text and Fig. 10) are omitted for clarity.

Compound 20b has three Br⋯Br contacts: Br1⋯Br2 = 3.3465 (7) Å, between anion and cation, is very short, whereas the other two, Br1⋯Br3(2 − x, −y, −z) = 3.7995 (7) and Br3⋯Br4(1 + x, −1 + y, z) = 3.8361 (7) Å are long. There are also two S⋯Br contacts, one short and one long, namely S1⋯Br4 = 3.5208 (13) and S1⋯Br5(1 − x, 1 − y, 1 − z) = 3.8555 (13) Å. These combine to form a layer structure parallel to (110) (Fig. 24).

Figure 24 Layer structure of 20b viewed perpendicular to (110). Dashed lines indicate short (thick) or long (thin) Br⋯Br and S⋯Br contacts. The horizontal direction is [001] and the vertical direction [10]. The anions based on Au2 are viewed edge-on, so that the atom Au2 is obscured by Br5.

4. Database survey

The searches employed the routine ConQuest (Bruno et al., 2002), part of Version 2022.3.0 of the Cambridge Structural Database (Groom et al., 2016).

Except for the structures in our previous work, no hits were registered for the atom sequence P—(S or Se)—(Cl or Br) with coordination numbers restricted to 2 for S/Se and 1 for Cl/Br (but with unrestricted bond orders). To obtain usable values for the E—X single bond lengths, we therefore searched for the sequence C—(S or Se)—(Cl or Br), on the principle that phospho­rus and carbon are in many respects similar (see e.g. Dillon et al., 1998). We obtained average values of 2.021, 2.224, 2.201 and 2.334 Å for S—Cl (20 values), S—Br (11 values), Se—Cl (12 values) and Se—Br (10 values) bonds, respectively. These are in reasonable agreement with our values given above. Care was, however, necessary in inter­preting the search output, because several hits with short intra­molecular contacts (some as short as 2.0 Å for Se⋯O, but not marked as bonds in the Database) involved three-coordinate selenium and, hence, needed to be removed. Thus the compound chloro­(8-(N,N-di­methyl­amino)­naphthyl­selenium(II) (Panda et al., 1999; refcode LIWYIZ), with an intra­molecular Se—N distance of 2.174 (5) Å and a long Se—Cl bond trans to the N atom, was drawn as a formula without an Se—N bond (and therefore, not unreasonably, coded accordingly in the CCDC). The distance was described as ‘non-bonded’, but the displacement ellipsoid plot included this as a normal bond. There seems to be some confusion in the older literature as to what constitutes a bond in such systems.

Similarly, a search for the atom sequence C₃P—S—C, with coordination numbers restricted to 4 for P and 2 for S, gave 19 hits and 21 P—S bond lengths, averaging to 2.076 Å. The analogous search using selenium gave 24 hits and 35 P—Se bond lengths, with an average of 2.233 Å. These are slightly shorter than our average values given above.

5. Synthesis and crystallization

For several of the compounds, the syntheses can be found in the PhD thesis of D. Upmann (Upmann, 2015). There was however a general problem of incomplete reactions, despite the use of excess oxidants PhICl₂ or Br₂. The following attempted, but not entirely successful, syntheses do not appear there:

Compound 17a: 212 mg (0.5 mmol) of ⁱPr₃PSAuCl and 344 mg (1.25 mmol) of PhICl₂ were each dissolved in 10 mL of di­chloro­methane. The solutions were combined and stirred for 30 min, during which time the solution changed from red to yellow; the solvents were then removed under vacuum. All attempts to isolate the product from this solution proved to be unsuccessful because intra­ctable oils or gums were formed; drying and recrystallization generally led to the separation of unidentified insoluble solids. ³¹P-NMR (81 MHz, CDCl₃, 300 K): δ [ppm] 92.56, ¹J_P–Se 416.3 Hz. Despite the failure to prepare the substance in qu­antity, a few single crystals (coated with an adhesive gum) were obtained by overlaying a solution in di­chloro­methane with n-pentane (or diethyl ether) and storing it in a refrigerator (276 K) over the weekend.

Compound 20a: Pilot experiments suggested that a large excess of PhICl₂ was necessary for complete reaction. 91.8 mg (0.197 mmol) of ^tBu₃PSAuCl and 541 mg (1.97 mmol) of PhICl₂ were each dissolved in 3 mL of di­chloro­methane. The solutions were combined; the mixture was then overlayered with n-pentane and stored in a refrigerator (276 K) for 7 d. However, no crystals formed. The solvents were then removed under vacuum. The solid residue was washed with n-pentane and recrystallized from di­chloro­methane/n-pentane. Yield 77 mg (0.127 mmol, 64%). However, the elemental analysis was poor and some colourless crystals of PhICl₂ were identified by their cell constants. ³¹P-NMR (81 MHz, CDCl₃, 300 K): δ [ppm] 90.18.

Compound 21a: 236 mg (0.5 mmol) of ⁱPr₃PSeAuCl and 344 mg (1.25 mmol) of PhICl₂ were dissolved in 10/9 mL of di­chloro­methane, respectively. The solutions were combined and stirred for 30 min, during which time the solution changed from red to yellow; the solvents were then removed under vacuum. The product proved to be very sensitive to air and moisture, and decomposed rapidly in solution. ³¹P-NMR (81 MHz, CDCl₃, 300 K): δ [ppm] 92.56, ¹J_P–Se 416 Hz. Despite the failure to prepare the substance in qu­antity, single crystals were obtained by overlaying a solution in di­chloro­methane with n-pentane and storing it in a refrigerator (276 K) over the weekend.

Compounds 17b and 21b: Treatment of solutions of ⁱPr₃PEAuBr₃ in di­chloro­methane with excess elemental bromine led to solutions whose ³¹P-NMR spectra showed the presence of both starting material and product (17b δ 84.15; 21b δ 80.47). Removal of the solvent, followed by crystallization attempts, led to some single crystals of the products. For 21b, the NMR spectrum was of poor quality and no P–Se coupling was detected.

Compounds 20b and 24b: Treatment of solutions of [(^tBu₃PE)₂Au][AuBr₄] (the syntheses and structures of these are still to be published) in di­chloro­methane with excess elemental bromine led to solutions whose ³¹P-NMR spectra showed the presence of both starting material and product (20b δ 91.16; 24b δ 88.08). Removal of the solvent, followed by crystallization attempts, led to some single crystals of 20b (but not of 24b). For 24b, the NMR spectrum was of poor quality and no P–Se coupling was detected.

6. Refinement

Details of the measurements and refinements are given in Table 33. Structures were refined anisotropically on F². Methine hydrogens were included at calculated positions and refined using a riding model with C—H = 1.00 Å and U(H) = 1.2 × U_eq(C). Methyl groups were refined, using the command ‘AFIX 137’, as idealized rigid groups allowed to rotate but not to tip, with C—H = 0.98 Å, H—C—H = 109.5° and U(H) = 1.5 × U_eq(C). This procedure is less reliable for heavy-atom structures, so that any postulated hydrogen bonds involving methyl hydrogen atoms should be inter­preted with caution.

Table 33 Experimental details   17a 18a 19a 20a 21a Crystal data Chemical formula (C9H21ClPS)[AuCl4] (C10H23ClPS)[AuCl4] (C11H25ClPS)[AuCl4] (C12H27ClPS)[AuCl4] (C9H21ClPSe)[AuCl4] Mr 566.50 580.53 594.55 608.58 613.40 Crystal system, space group Monoclinic, P21/n Triclinic, P Monoclinic, C2/c Monoclinic, P21/n Triclinic, P Temperature (K) 100 100 100 100 100 a, b, c (Å) 13.3577 (5), 10.0877 (3), 13.9182 (5) 7.5619 (4), 8.7408 (4), 15.4558 (6) 33.653 (3), 7.7933 (3), 16.212 (2) 9.7661 (3), 12.5787 (3), 16.9776 (5) 7.4202 (3), 8.5966 (3), 15.3980 (6) α, β, γ (°) 90, 106.290 (4), 90 84.346 (4), 78.306 (4), 66.915 (5) 90, 113.861 (8), 90 90, 103.887 (3), 90 97.497 (3), 100.128 (4), 109.324 (4) V (Å3) 1800.18 (11) 920.07 (8) 3888.5 (6) 2024.67 (10) 893.42 (6) Z 4 2 8 4 2 Radiation type Mo Kα Mo Kα Mo Kα Mo Kα Mo Kα μ (mm−1) 9.10 8.90 8.43 8.10 11.09 Crystal size (mm) 0.2 × 0.1 × 0.03 0.2 × 0.18 × 0.05 0.2 × 0.02 × 0.01 0.15 × 0.07 × 0.04 0.18 × 0.15 × 0.10   Data collection Diffractometer Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Absorption correction Multi-scan (CrysAlis PRO; Rigaku OD, 2015) Multi-scan (CrysAlis PRO; Rigaku OD, 2015) Multi-scan (CrysAlis PRO; Rigaku OD, 2015) Multi-scan (CrysAlis PRO; Rigaku OD, 2015) Multi-scan (CrysAlis PRO; Rigaku OD, 2015) Tmin, Tmax 0.359, 1.000 0.316, 1.000 0.698, 1.000 0.756, 1.000 0.631, 1.000 No. of measured, independent and observed [I > 2σ(I)] reflections 65964, 4458, 3807 50339, 5453, 4838 84613, 4815, 3861 8891, 8891, 4196 106851, 5322, 4900 Rint 0.056 0.032 0.096 – 0.039 θ values (°) θmax = 28.3, θmin = 2.5 θmax = 30.8, θmin = 2.5 θmax = 28.3, θmin = 2.5 θmax = 31.3, θmin = 2.2 θmax = 30.9, θmin = 2.6 (sin θ/λ)max (Å−1) 0.667 0.721 0.667 0.731 0.722   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.040, 0.102, 1.08 0.017, 0.036, 1.05 0.033, 0.064, 1.04 0.022, 0.045, 0.77 0.016, 0.033, 1.10 No. of reflections 4458 5453 4815 8891 5322 No. of parameters 160 174 191 194 164 No. of restraints 0 0 1 0 0 H-atom treatment H-atom parameters constrained H-atom parameters constrained H-atom parameters constrained H-atom parameters constrained H-atom parameters constrained Δρmax, Δρmin (e Å−3) 5.27, −1.24 1.32, −1.07 2.43, −1.87 1.12, −0.92 0.83, −0.85 Extinction method None Fc* = kFc[1 + 0.001 Fc2λ3/sin(2θ)]-1/4 (SHELXL2019/3; Sheldrick, 2015) None None Fc* = kFc[1 + 0.001 Fc2λ3/sin(2θ)]-1/4 (SHELXL2019/3; Sheldrick, 2015) Extinction coefficient – 0.00167 (11) – – 0.00346 (11)   22a 23a 17b 18b 19b Crystal data Chemical formula (C10H23ClPSe)[AuCl4] (C11H25ClPSe)[AuCl4] (C9H21BrPS)[AuBr4] (C10H23BrPS)[AuBr4] (C11H25BrPS)[AuBr4] Mr 627.43 641.46 788.80 802.83 816.86 Crystal system, space group Triclinic, P Monoclinic, C2/c Triclinic, P Triclinic, P Monoclinic, P21/n Temperature (K) 100 100 100 100 100 a, b, c (Å) 7.5836 (2), 8.7603 (2), 15.4719 (6) 33.7472 (6), 7.79306 (8), 16.2575 (3) 7.8543 (4), 8.0592 (4), 15.3505 (7) 7.8455 (6), 9.1380 (6), 15.5440 (9) 12.4712 (4), 10.3712 (3), 16.2524 (5) α, β, γ (°) 84.445 (3), 78.641 (3), 67.128 (3) 90, 113.582 (3), 90 76.717 (4), 83.169 (4), 87.722 (4) 86.600 (5), 81.097 (6), 64.862 (6) 90, 92.724 (3), 90 V (Å3) 928.28 (5) 3918.54 (14) 938.89 (8) 996.65 (13) 2099.73 (11) Z 2 8 2 2 4 Radiation type Mo Kα Mo Kα Mo Kα Mo Kα Mo Kα μ (mm−1) 10.67 10.12 18.65 17.57 16.69 Crystal size (mm) 0.2 × 0.2 × 0.03 0.35 × 0.2 × 0.04 0.2 × 0.08 × 0.05 0.25 × 0.1 × 0.03 0.35 × 0.25 × 0.10   Data collection Diffractometer Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Oxford Diffraction Xcalibur, Eos Absorption correction Multi-scan (CrysAlis PRO; Rigaku OD, 2015) Multi-scan (CrysAlis PRO; Rigaku OD, 2015) Multi-scan (CrysAlis PRO; Rigaku OD, 2015) Multi-scan (CrysAlis PRO; Rigaku OD, 2015) Multi-scan (CrysAlis PRO; Rigaku OD, 2015) Tmin, Tmax 0.232, 1.000 0.308, 1.000 0.247, 1.000 0.097, 0.621 0.068, 0.286 No. of measured, independent and observed [I > 2σ(I)] reflections 102916, 5490, 4978 257492, 6028, 5453 54229, 5646, 5089 26487, 5731, 5030 70058, 6335, 5041 Rint 0.042 0.058 0.043 0.045 0.065 θ values (°) θmax = 30.9, θmin = 2.5 θmax = 30.9, θmin = 2.5 θmax = 30.9, θmin = 2.6 θmax = 30.8, θmin = 2.5 θmax = 30.9, θmin = 2.3 (sin θ/λ)max (Å−1) 0.722 0.723 0.721 0.720 0.723   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.021, 0.054, 1.05 0.021, 0.043, 1.11 0.021, 0.040, 1.08 0.027, 0.052, 1.06 0.033, 0.061, 1.09 No. of reflections 5490 6028 5646 5731 6335 No. of parameters 174 191 164 173 183 No. of restraints 0 0 0 0 0 H-atom treatment H-atom parameters constrained H-atom parameters constrained H-atom parameters constrained H-atom parameters constrained H-atom parameters constrained Δρmax, Δρmin (e Å−3) 1.86, −1.59 1.13, −1.20 1.42, −1.15 2.15, −2.24 2.43, −1.44 Extinction method Fc* = kFc[1 + 0.001 Fc2λ3/sin(2θ)]-1/4 (SHELXL2019/3; Sheldrick, 2015) None Fc* = kFc[1 + 0.001 Fc2λ3/sin(2θ)]-1/4 (SHELXL2019/3; Sheldrick, 2015) None None Extinction coefficient 0.00144 (18) – 0.00112 (7) – –   20b 21b 22b 23b Crystal data Chemical formula (C12H27BrPS)[AuBr4] (C9H21BrPSe)[AuBr4] (C10H23BrPSe)[AuBr4] (C11H25BrPSe)[AuBr4] Mr 830.88 835.70 849.73 863.76 Crystal system, space group Triclinic, P Triclinic, P Triclinic, P Monoclinic, P21/n Temperature (K) 100 100 100 101 a, b, c (Å) 10.2218 (5), 10.8085 (6), 11.1163 (5) 7.9212 (4), 8.0606 (4), 15.2911 (8) 7.8155 (3), 9.1505 (3), 15.5221 (5) 12.3529 (4), 10.4233 (4), 16.4635 (5) α, β, γ (°) 70.909 (4), 71.516 (5), 75.645 (4) 76.817 (5), 82.668 (5), 87.728 (4) 85.965 (2), 80.294 (3), 66.049 (3) 90, 93.453 (3), 90 V (Å3) 1086.40 (10) 942.78 (9) 999.97 (6) 2115.97 (12) Z 2 2 2 4 Radiation type Mo Kα Mo Kα Mo Kα Mo Kα μ (mm−1) 16.13 20.39 19.23 18.18 Crystal size (mm) 0.1 × 0.05 × 0.002 0.1 × 0.1 × 0.05 0.3 × 0.2 × 0.03 0.2 × 0.1 × 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, 2015) Multi-scan (CrysAlis PRO; Rigaku OD, 2015) Multi-scan (CrysAlis PRO; Rigaku OD, 2015) Multi-scan (CrysAlis PRO; Rigaku OD, 2015) Tmin, Tmax 0.284, 1.000 0.434, 1.000 0.202, 1.000 0.122, 0.713 No. of measured, independent and observed [I > 2σ(I)] reflections 73343, 6283, 5151 69642, 5661, 4881 52431, 5847, 5198 7063, 7063, 4089 Rint 0.078 0.057 0.050 – θ values (°) θmax = 30.0, θmin = 2.4 θmax = 30.9, θmin = 2.6 θmax = 30.9, θmin = 2.4 θmax = 28.3, θmin = 2.3 (sin θ/λ)max (Å−1) 0.704 0.723 0.722 0.667   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.032, 0.066, 1.05 0.024, 0.045, 1.06 0.025, 0.063, 1.04 0.034, 0.061, 0.81 No. of reflections 6283 5661 5847 7063 No. of parameters 193 164 173 184 No. of restraints 0 0 0 66 H-atom treatment H-atom parameters constrained H-atom parameters constrained H-atom parameters constrained H-atom parameters constrained Δρmax, Δρmin (e Å−3) 1.56, −1.67 1.53, −1.01 1.71, −1.44 1.72, −1.10 Extinction method None Fc* = kFc[1 + 0.001 Fc2λ3/sin(2θ)]-1/4 (SHELXL2019/3; Sheldrick, 2015) None None Extinction coefficient – 0.00116 (7) – – Computer programs: CrysAlis PRO (Rigaku OD, 2015), SHELXS97 (Sheldrick, 2008), SHELXL2019/3 (Sheldrick, 2015) and XP (Bruker, 1998).