2.3.1. Compound 1

The difference Fourier synthesis shows one maximum at the midpoint of two oxygen positions with the refinement resulting in grossly anisotropic displacement parameters corresponding to a `cigar-shaped' ellipsoid. The disorder is refined using the so-called split-atom model strategy. The two partial atoms are refined independently, even with the sum of their site occupancies constrained to unity (Fig. 2). The hydrogen atoms were located by Fourier difference except for the hydrogen atoms located on oxygen sites which were placed at calculated positions. All hydrogen atoms were refined isotropically.

Figure 2 Oxygen splitting in compound 1. Color coding for atoms: red: oxygen; dark gray: carbon; violet: nitro­gen; light grey: platinum; green: chloride.

2.3.2. Compound 2

The asymmetric unit includes two disordered complexes: the disorder of the first complex (a) involves the methyl in the tertiary butyl group [–C(CH₃)₃] and the oxygen atom in the amide moiety (NCO). The split-atom model has been used to model the disorder (Fig. 3). Since the hydrogen atoms bound to the split oxygen atoms have not been found by Fourier difference, they were added manually and refined isotropically. In the second complex (b) in the asymmetric unit of compound 2 shows an electron density symmetrically distributed around a a local plane through the N2 and C2 atoms of the pivalo­amide group. The disorder was modeled by splitting the C1 carbon atom and the tertiary butyl group (Fig. 4).

Figure 3 Oxygen and methyl splitting in compound 2a. Color coding for atoms: red: oxygen; dark gray: carbon; violet: nitro­gen; light grey: platinum; green: chloride.

Figure 4 Amide ligand splitting in compound 2b. Color coding for atoms: red: oxygen; dark gray: carbon; violet: nitro­gen; light grey: platinum; green: chloride.

3.1.1. Compound 1: platinum(II)

The H¹-NMR spectrum was recorded on a Bruker Avance DPX 300 MHz WB instrument at 295 K in acetone-d₆. ¹H chemical shifts were referenced to TMS by using the residual protic peak of acetone-d₆ as internal reference. The ¹H-NMR spectrum (Fig. 5) shows two broad signals at ∼11.08 ppm and ∼8.31 ppm assigned to the OH and NH protons in the amide ligand, respectively, and three aromatic proton contributions at 7.96 ppm, 7.68 ppm and 7.58 ppm from the ortho, para and meta protons, respectively.

Figure 5 1H-NMR spectrum of compound 1. Chemical shift (ppm): a δ[OH] ∼11.08, b δ[NH] ∼8.31, c δ[Ph(o)] ∼7.96, δ[Ph(p)] ∼7.68, δ[Ph(m)] ∼7.58. (m = meta, o = ortho, p = para).

3.1.2. Compound 2: platinum(IV)

¹H-NMR spectrum was collected at 295 K in CDCl₃. ¹H chemical shifts were referenced to TMS by using the residual protic peak of CDCl₃ as internal reference. The ¹H-NMR spectrum (Fig. 6) contains a sharp signal at ∼1.33 δ and a broad signal at ∼4.63 δ assigned to the tert-butyl group and NH₃ protons, respectively, in good agreement with a previous work on a trans-Pt^III complex with similar ligands {δ[tert-butyl] ∼1.20, δ[NH₃] ∼5.00 in Vinci & Chateigner (2022)}. Moreover, two single proton resonances at ∼6.90 δ and 10.25 δ can be assigned to the NH and OH groups in the amide moiety. It is worth noting that the shape of the hydroxyl proton peak depends upon the nature of R [–C(CH₃)₃ in compound 2 or —C₆H₅ in compound 1]: the signal is sharp for the ^tBu derivative and broader for the phenyl group. This feature may be explained by the chemical exchange process involving the hydroxyl proton and water impurities. The exchange rate is expected to increase with the acidity of the hydroxyl proton.

Figure 6 1H-NMR spectrum of compound 2. Chemical shift (ppm): a δ[OH] ∼10.25, b δ[NH] ∼6.9, c δ[NH3] ∼4.63 and d δ[tert-butyl] ∼1.33.

3.2.1. Compound 1: platinum(II)

The asymmetric unit comprises half a molecule of the trans-[PtCl₂{HN=C(OH)C₆H₅}₂] complex. The structure is composed of one platinum cation, coordinated by two chloride anions and two benzamide ligands. The central platinum atom lies on the crystallographic inversion center in a slightly distorted square planar coordination geometry (Fig. 7). This distortion is due to the differences in the metal–ligand bond lengths as reported for analogous complexes (Fabijańska et al., 2015). The N1, C1, C2 and O1 ligand atoms are coplanar as expected owing to the sp² hybridization of the N1 and C1 atoms linked with a double bond. The Pt—N bond distance length, 2.0072 (18) Å, agrees with previously reported values for trans-complexes with similar ligands [Pt—N from the literature: 2.01 (2)–2.067 (4) Å; Fabijańska et al., 2015; Grabner & Bukovec, 2015; Cini et al., 1999]. The lengths of the C1—N1, C1—O1 and C1—O2 bonds [1.274 (3), 1.325 (6) and 1.327 (7) Å, respectively] are shorter than those found for the corresponding single bonds, but larger than double bonds [from literature: C(sp³)—N(sp³) = 1.469 (14) Å, C(sp²)=N(sp²) = 1.279 (8) Å, C(sp³)—OH = 1.426 (11) Å, C(sp²)=O = 1.210 (8) Å; Allen et al., 1987]. This means that a double bond is delocalized over the N—C—O moiety. The same behavior has already been reported for N-coordinated amidato (Erxleben et al., 1994) and imino­ether ligands (Casas et al., 1991). The length of the platinum–chloride bond, 2.3084 (6) Å, is nearly the same as found in complexes with the same trans influence. For example, in trans-Pt(3-af)₂Cl₂ [where 3-af = 3-amino­flavone (3-amino-2-phenylchromen-4-one, C₁₅H₁₁NO₂) the Pt—Cl bond is 2.298 (1) Å; in trans-[PtCl₂(dmso)L] [where L = 3-(pyridin-2-yl­methyl)­oxazolidin-2-one], the Pt—Cl bonds are 2.2965 (9) and 2.3025 (8) Å, whereas in trans-[PtCl₂{HN=C(OH)C(CH₃)₃}₂] an average value of 2.299 (3) Å is observed (Fabijańska et al., 2015; Van Beusichem & Farrell, 1992; Cini et al., 1999). The Pt1—N1—C1 angle is ∼137 (2)°, which is well above the expected values (120°), in agreement with the values observed for trans-[PtCl₂{HN=C(OH)C(CH₃)₃}₂] and trans-[PtCl₂{HN=C(OMe)^tBu}₂] complexes (Cini et al., 1999). The benzamide plane and the platinum coordination plane, PtN₂Cl₂, make a dihedral angle of 20.86°. This orientation optimizes the intramolecular hydrogen bond interaction within the molecule.

Figure 7 ORTEP drawing of compound 1 with intramolecular hydrogen bond interactions: [O1⋯Cl1 2.978 Å, H12⋯Cl1 2.184 Å, O1—H12⋯Cl1 163.56°] and [O2⋯Cl1 2.956 Å, H21⋯Cl1 2.165 Å, O2—H21⋯Cl1 162.04°]. The ellipsoids enclose 30% probability. Color coding for atoms: white: hydrogen; green: chlorine; blue: nitro­gen; gray: carbon; red: oxygen. Symmetry code (i): −x + 1, −y + 2, −z.

The hydroxyl group points toward the chloride ligand resulting in an intramolecular hydrogen bond that stabilizes the complex (Fig. 7).

The molecular crystal packing is mainly governed by π⋯π stacking interactions and van der Waals intermolecular forces, involving the benzene ring of adjacent molecules with an intermolecular distance of ∼3.62 Å (Sinnokrot & Sherrill, 2006). The van der Waals intermolecular interactions involve hydrogen of the benzene ring and oxygen atom of the hydroxyl group [C7⋯O1A 3.280 (3) Å, H31⋯O2 2.613  (1) Å, C3—H31⋯O2 146.03 (8)°], resulting in the crystal packing shown in Fig. 8.

Figure 8 Molecular packing of compound 1, view normal to the (100). Color coding for atoms: white: hydrogen; green: chlorine; blue: nitro­gen; gray: carbon; red: oxygen.

3.2.2. Compound 2: platinum(IV)

The crystal structure features two enantiomers in the cell [Flack parameter = 0.47 (1)]. The Pt^IV atom has an octahedral coordination geometry with four chloride ligands and two nitro­gen atoms (with hybridization sp² and sp³ for amide and ammine ligands, respectively) in trans configuration (Fig. 9). The bond distances between platinum and ligands (Pt—N and Pt—Cl distances in Table 2) are in good agreement with values found previously for compound 1 and in the literature for platinum(III) and platinum(II) complexes (Vinci & Chateigner, 2022; Fabijańska et al., 2015; Grabner & Bukovec, 2015; Cini et al., 1999; Van Beusichem & Farrell, 1992). In the amide ligand, the C—N and C—O distances average 1.20 (7) Å and 1.13 (1) Å, respectively, due to the double bond delocalization over the N—C—O moiety as observed also for compound 1. The C6—N4—Pt2, Pt1—N2—C11 and Pt1—N2—C10 angles are 132.7 (5)°, 140.2 (5)° and 141.3 (4)°, respectively, similar to the angle found for compound 1. The larger angle is probably due to intramolecular hydrogen bonds involving the hydroxyl hydrogen and the chloride ligand (Fig. 10). The bond angles within the coordination sphere deviate significantly from the ideal value of 90°. For instance, in compound 2 with the atom labeled Pt2 (Fig. 9), two angles are particularly large [93.67 (19)° and 93.60 (17)°] for N4—Pt2—Cl5 and N4—Pt2—Cl8 angles, respectively) and two are particularly small [87.57 (16)° and 86.60 (19)°] for N3—Pt2—Cl6 and N3—Pt2—Cl8 angles, respectively). This feature is due to the hydrogen bond interactions between the hydroxyl group and the chloride ligands. The same behavior has been observed in the second enantiomer in the unit cell.

Figure 9 ORTEP diagram of two enantiomers of compound 2. The ellipsoids enclose 30% probability. Color coding for atoms: white: hydrogen; green: chlorine; blue: nitro­gen; gray: carbon; red: oxygen.

Figure 10 ORTEP drawing of two molecules of compound 2 linked by intramolecular hydrogen bonds (Table 3). The ellipsoids enclose 30% probability. Color coding for atoms: white: hydrogen; green: chlorine; blue: nitro­gen; gray: carbon; red: oxygen.

The molecular packaging (Fig. 11) is governed by hydrogen bonds and van der Waals interactions (Table 3). The intermolecular hydrogen bonds are observed between amide and chloride ligands. The intermolecular van der Waals interactions occur between the tert-butyl groups and the chloride ligands.

Figure 11 ORTEP drawing of packing of compound 2 governed by intermolecular hydrogen bonds and van der Waals interactions. The ellipsoids enclose 30% probability. Atom color coding: white for hydrogen, green for chlorine, blue for nitro­gen, gray for carbon and red for oxygen.