1. Chemical context

Phospho­ramide/phosphinamide moieties are well-known structural motifs of some bioactive products and drugs (Warren et al., 2016; Palacios et al., 2005). There are also reports on their applications in flame retardants (Nguyen & Kim, 2008), ligands (Wang et al., 2021; Ferentinos et al., 2019; Zhang et al., 2019), extractants (Akbari et al., 2019), anion transporters (Cranwell et al., 2013) and catalysts (Klare et al., 2014).

Some of these characteristics are general for phospho­r­amide/phosphinamide compounds, and can be influenced by the groups attached to the common NP=O unit. Typically, the donor property of the phosphoryl group is beneficial in sorption processes, inter­actions with some enzymes and the formation of hydrogen bonds (Corbridge, 2000). The subfamily to which the compounds belong also plays a role. For example, phosphinicamides with the (C)₂P(O)(N) skeleton are found to have higher electron-donor properties with respect to amido­phospho­diesters with the (O)₂P(O)(N) skeleton. The chirality may also be essential for some partic­ular applications, such as the manufacture of drugs and the planning of some reactions related to different reactivities of diastereotopic groups (Nakayama & Thompson, 1990), enanti­oseparation (Ahmadabad et al., 2019) and enanti­o­selective catalysis (Liao et al., 2019).

Recently, we have reported some single-enanti­omer small mol­ecules, belonging to the phospho­ramide family, and phosphor­amide-based macromolecules/hydro­gels (Ahmadabad et al., 2019; Taherzadeh et al., 2021; Sabbaghi et al., 2019). The related synthesis procedure could also be developed for manufacturing phosphinamide-based materials. Moreover, we are inter­ested in studying the differences between two diastereotopic groups in chiral structures. The reason for such attention is the asymmetric induction at phospho­rus by the chiral group, which causes different reactivities of two diastereotopic groups (Nakayama & Thompson, 1990). These differences were investigated in organic syntheses for the creation of new stereocentres and also can be used for the design and synthesis of ligands with different donor properties of the diastereotopic groups.

In the present work, we continue with the synthesis of new chiral (C₆H₅O)₂P(O)[NH-(+)CH(C₂H₅)(C₆H₅)] phospho­r­amide, (I), and (C₆H₅)₂P(O)[NH-(+)CH(C₂H₅)(C₆H₅)] phosphinamide, (II) to study structural differences of two diastereotopic C₆H₅O/C₆H₅ groups, caused by the same chiral amine. Structure I is the enanti­omer of the previously reported (C₆H₅O)₂P(O)[NH-(–)CH(C₂H₅)(C₆H₅)] (Sabbaghi et al., 2011). The investigation is completed by considering structural differences/similarities of diastereotopic groups in analogous chiral structures retrieved from the CSD (Groom et al., 2016). The main features of the NMR parameters of the diastereotopic groups in I and II are also discussed.

2. Structural commentary

Compound I crystallizes in the ortho­rhom­bic chiral space group P2₁2₁2₁, with the asymmetric unit composed of one amido­phospho­diester mol­ecule (Fig. 1). Compound II is triclinic in chiral space group P1, and its asymmetric unit consists of two phosphinicamide mol­ecules (Fig. 2). Selected bond lengths and angles are presented in Tables 1 and 2. All bond distances and angles are within the values observed in analogous structures (Vahdani Alviri et al., 2020; Hamzehee et al., 2017).

Figure 1 The asymmetric unit of I, showing the atom-numbering scheme for non-hydrogen atoms and displacement ellipsoids at 50% probability level. Hydrogen atoms are drawn as spheres of arbitrary radii.

Figure 2 Displacement ellipsoid plot (50% probability) of the asymmetric unit of II, showing the atom-numbering scheme for non-hydrogen atoms. Hydrogen atoms are drawn as spheres of arbitrary radii.

The P atoms display a distorted tetra­hedral environment, (O)₂P(O)(N) for I and (C)₂P(O)(N) for II, and the maximum/minimum bond angles at phospho­rus are related to O=P—O/O—P—O and O=P—N/N—P—C. The differences between maximum and minimum values are about 16.8° for I and 17.5°/16.9° for the two symmetry-independent mol­ecules of II. The P—N—C angles in I and II, for example, P1—N3—C4 angle in II of 120.91 (14)° (Table 2), demonstrate that the hybridization state of nitro­gen atoms is close to sp². The P—O—C angles of I, 127.68 (17)°/121.91 (16)°, similarly show the hybridization state of the ester oxygen atoms is close to sp².

The structure I is similar to its S-enanti­omer (EXIQIM; Sabbaghi et al., 2011) regarding space group, unit cell and other structural parameters; the only substantial difference is related to the configuration at dissymmetric carbon atoms. Fig. 3a shows the overlay of the inverted structure of I with EXIQIM. The overlay is calculated with a root-mean-square deviation (r.m.s.d.) of 0.0089 Å and a maximum deviation of 0.0153 Å.

Figure 3 (a) Overlay of EXIQIM (grey) and inverted I (blue). (b) Overlay of two symmetry-independent mol­ecules of II (green and blue show mol­ecules P1 and P25, respectively).

The P=O bond in I, 1.469 (2) Å, is shorter than the P=O bonds in II, 1.4846 (15)/1.4933 (15) Å, and the same is true about the P—N bonds [1.619 (2) Å in I, and 1.6367 (19)/1.6426 (19) Å in II]. The differences result from the effect of electronegative oxygen atoms of two C₆H₅O groups in I attached to phospho­rus, while in II, there are two C₆H₅ groups. The longer P—N bond in II is also caused by the steric effects of two phenyl groups directly attached to phospho­rus. Minor differences are observed for the bond lengths related to the diastereotopic pairs. Typically, the P—O and P—C bonds in I and two independent mol­ecules of II are 1.581 (2)/1.592 (2) Å, 1.802 (2)/1.808 (2) Å and 1.808 (2)/1.797 (2) Å.

In compound I, the N—H unit adopts an anti­periplanar (–ap) orientation with respect to the P=O group (based on the O=P—N—H torsion angle of −157.18°), and in two symmetry-independent mol­ecules of II, the same units adopt synclinal (–sc and +sc) conformations (the torsion angles are −80.63° and +84.78°). The different conformation of II (in comparison to I) results from intra­molecular rotations of the chiral amine, and the two independent mol­ecules feature different rotations, but with a similar O=P—N—H conformation.

In II, the symmetry-independent mol­ecules are similar concerning the bond lengths and angles (see Table 2). However, they show some differences in torsion angles (and conformations). Typically, the conformations in the CH₃—CH₂—CH—NH—P=O segment are defined by the C—C—C—N/C—C—N—P/C—N—P=O torsion angles, and the values in the P1 molecule of +173.7 (2)°/−98.2 (2)°/60.7 (2)° correspond to +ap/−ac/+sc conformations (ac = anti­clinal). Similar torsion angles in the other mol­ecule, −178.3 (2)°/−158.6 (2)°/−62.0 (2)°, define −ap/–ap/−sc conformations. The other notable difference between the two mol­ecules is reflected in the direction of the phenyl ring of the chiral segment with respect to the P=O group (an opposite direction in the mol­ecule P1 and the same direction in the second mol­ecule). Fig. 3b shows the overlay of two mol­ecules, and the root-mean-square deviation (r.m.s.d.) of the fit of them is 1.3533 Å with a maximum deviation of 4.6684 Å. The noted difference is reflected in the spatial distances of phenyl groups bonded to P and the phenyl group of chiral amine in the two mol­ecules. The differences in diastereotopic phenyl rings in each mol­ecule can also be described by their distances from the phenyl ring of the chiral amine.

For I, the distances between the centroid of the phenyl ring of chiral amine and the centroids of two diastereotopic phenyl groups are 5.0848 (1) and 7.9514 (1) Å. For the two symmetry-independent mol­ecules of II, equivalent distances are 5.5767 (5)/7.0325 (6) Å and 7.1614 (6)/6.4951 (3) Å. These spatial distances show that one of the diastereotopic phenyl rings is significantly closer to the phenyl of the chiral amine. The differences in these spatial distances are pronounced in I, where the flexibility is greater (because of the existence of the P—O—C segment and the possibility of rotation).

In I, the conformations of phenyl rings can be introduced by the C—C—O—P torsion angles, which are 32.1 (3)°/−149.9 (2)° and 86.7 (3)°/−98.0 (3)° according to the +sc−ac conformations for both phenyl rings. In the structure of II, the C—C—P=O torsion angles were considered for checking the conformations of the phenyl rings. The values are 173.8 (2)°/−10.4 (2)° and 25.4 (2)°/−158.0 (2)° (+ap−sp and +sp−ap) in one mol­ecule and 10.8 (2)°/−169.6 (2)° and −18.4 (2)°/163.0 (2)° (+sp−ap and −sp+ap) in the other mol­ecule, which also show similar conformations.

3. Supra­molecular features

In the crystal structures of I and II, the mol­ecules are assembled in a chain arrangement through N—H⋯O(P) hydrogen bonds along [100] (Fig. 4, Tables 3 and 4). The N—H⋯O(P) hydrogen bond in I is weaker than in II (H⋯O distances are 2.24 and 1.97/2.08 Å, respectively). This weakness is the result of the lower hydrogen-bond acceptor capability expected for the phosphoryl group of an (O)₂(N)P(O)-based structure, compared to the phosphoryl group of a (C)₂(N)P(O)-based structure, and is due to the two atoms with a higher electronegativity bonded to the phospho­rus atom. The effect of different electronegativities was previously noted (see above) for different P=O bond lengths.

Table 4 Hydrogen-bond geometry (Å, °) for II D—H⋯A D—H H⋯A D⋯A D—H⋯A N27—H271⋯O2i 0.84 2.08 2.923 (4) 176 (2) N3—H31⋯O26 0.86 1.97 2.817 (4) 173 (2) Symmetry code: (i) .

Figure 4 Crystal packing of I (top) and II (bottom). The red, orange, light-blue and pink balls show oxygen, phospho­rus, nitro­gen and hydrogen attached to nitro­gen atoms. For I, carbon atoms and attached hydrogen atoms are shown in light green. For II, two-symmetry independent mol­ecules are shown in light green and blue. The dotted lines show N—H⋯O hydrogen bonds.

C—H⋯π inter­actions in I assemble the mol­ecules in a two-dimensional array in the ab plane. Fig. 5 shows the mol­ecular assembly formed by the N—H⋯O, C—H⋯O and possible C—H⋯π inter­actions, where the C—H⋯O inter­action does not change the dimensionality made by the N—H⋯O hydrogen bond. To show better the contact(s) contributing by each phenyl ring, the rings are distinguished by colours: green (C3–C8) and magenta (C11–C16) for the diastereotopic rings and grey (C19–C24) for the phenyl ring of the chiral amine. The green ring takes part in a C—H⋯π inter­action as a donor (the acceptor is the grey ring) (H⋯Cg = 2.81 Å). The magenta ring takes part in a C—H⋯π inter­action with an adjacent symmetry-related magenta ring (H⋯Cg = 3.23 Å) and also in a C—H⋯OP inter­action (H⋯O = 2.55 Å). The formed two-dimensional assembly is double-layered and has a thickness of 18.057 Å in the c-axis direction.

Figure 5 A view of the two-dimensional double-layered arrangement of I formed by N—H⋯O, C—H⋯O and C—H⋯π inter­actions (shown as black, blue and red dotted lines, respectively). The centroids of the phenyl rings taking part as acceptors in C—H⋯π inter­actions are shown as balls of the same colours as the corresponding ring.

In the structure of II, two possible C—H⋯π inter­actions exist (H⋯Cg distances of 3.41 and 3.49 Å), which do not change the dimensionality made by the N—H⋯O hydrogen bonds. In both C—H⋯π inter­actions, the H donors are chiral amines of two symmetry-independent mol­ecules (the ortho-hydrogen atom and the hydrogen of the CH₂ unit, as shown in Fig. 6). The acceptors are one of the diastereotopic phenyl rings of the molecule including atom P1 and the phenyl ring of the chiral amine in the other molecule.

Figure 6 A view of the one-dimensional arrangement of structure II formed by N—H⋯O and C—H⋯π inter­actions (shown as black and red dotted lines). Only the hydrogen atoms participating in these hydrogen-bond interactions are shown.

4. An overview of diastereotopic groups in analogous structures

The chiral structures with an R₂P(=X)—N—C(H)(C)(C—C) fragment (X = O, S, N; C is a dissymmetric carbon atom) were retrieved from the CSD to study possible structural differences for diastereotopic R groups; the metal complexes were not considered. The CSD (version 5.42 updated on Feb. 2021; Groom et al., 2016) comprises 48 such structures, of which two were unavailable. The remaining 46 structures include 79 pairs of diastereotopic P—Y (Y = C, O, N) bonds, and the structures have different skeletons, (C)₂P(O)(N), (C)₂P(S)(N), (C)₂P(N)(N), (O)₂P(O)(N) and (N)₂P(O)(N). The related bond lengths are given in Table S1 of the supporting inform­ation. The largest difference for the P—C bond lengths made by diastereotopic groups (0.025 Å) exceeds the largest differences for the P—O (0.017 Å) and P—N bond lengths (0.015 Å). The P—C, P—N and P—O bond lengths in these structures vary from 1.773 to 1.837 Å, 1.629 to 1.652 Å and 1.555 to 1.607 Å, respectively, with averages of 1.805, 1.643 and 1.580 Å.

The conformations of diastereotopic groups attached to phospho­rus were analysed in the structures analogous to I and II, i.e. with the O₂P and C₂P skeletons. Only three O₂P-based structures (with the oxygen atom attached to an arene ring) were found in the CSD. For the C₂P skeleton, 36 structures, including 64 R₂PX fragments, were checked, and the C—C—P=X (X = O, N, S) torsion angles were evaluated.

The C₂P-based structures mainly include Ph₂P(O) fragment (28 structures), similar to compound II; however, structures with Ph₂P(S) (seven structures), and (C₆H₁₁)₂P(=N) (one structure) fragments were also found. Both similar and different conformations were observed for diastereotopic groups. Details of the analysis are given in Table S2 and Fig. S1 of the supporting information. The torsion angles such as C—C—P=O of 0.04° in the structure with refcode MEFCIK (Sweeney et al., 2006) show the P=O group nearly in a plane where the phenyl ring also exists. Its complementary torsion angle for the other C—C—P=O related to this phenyl ring is 176.54°, and these two torsion angles define the sp+ap conformation of this phenyl ring with respect to the P=O group. On the other hand, most of the structures also include ±sp±ap conformations at least for one phenyl ring. The most populated conformations for diastereotopic fragments (sep­arated by "/") are ±sp±ap/±sp±ap (26 entries) and ±sp±ap/±sc±ac (23 entries). In the systems with phenyl rings directly attached to the phospho­rus atom, as a result of crowding, the simultaneous torsion angles around ±90° (a perpendicular conformation) for both phenyl rings were not found for any structure. In some cases, like in the structure with refcode VUGSOG (Yin et al., 2009) with close phenyl rings, the CH unit of one phenyl ring is directed toward the centroid of the second phenyl ring because of the formation of an intra­molecular C—H⋯π inter­action.

As a result of the existence of C—O—P moiety in the O₂P-based structures, the flexibility is expected to be higher than for Ph₂P-based structures; the three structures show different conformations but they include ±sc±ac conformations at least in one arene ring.

5. Hirshfeld surface analyses and fingerprint plots of structures I and II

To visualize and compare the inter­molecular contacts of I and II, the Hirshfeld surfaces (HS) mapped with d_norm and two-dimensional fingerprint plots (Spackman & Jayatilaka, 2009; Spackman et al., 2021) were generated using the CrystalExplorer program (Wolff et al., 2013). In the HS map of I (Fig. 7), the red areas are associated with the N—H⋯O, C—H⋯O and 2×C—H⋯π inter­actions [labels (i), (ii) and (iii)]. The contacts of I, obtained from the fingerprint plots, are H⋯H (57.3%), H⋯C (28.8%), H⋯O (12.7%) and O⋯C (1.2%). The O⋯C contact results from the near distance of two symmetry-related phen­oxy groups [O2(C3–C8)], through the ester oxygen atom and π-system.

Figure 7 Hirshfeld surface map generated for the structure I. Two mol­ecules are shown outside the surface to represent the N—H⋯O [label (i)], C—H⋯O [label (ii)] and typical C—H⋯π [label (iii)] inter­actions with the mol­ecule within the surface.

For II, the HS map was generated around two symmetry-independent mol­ecules step by step. Besides N—H⋯O hydrogen bonds, a significant H⋯H contact develops a red area, as seen in Fig. 8. This inter­action is between H231 of the phenyl ring of mol­ecule P1 connected to H301 of the chiral amine of the other mol­ecule. The H⋯H separation was obtained as 2.291 Å and 2.026 Å in the X-ray and Hirshfeld analyses, respectively (the neutron-normalized CH distance is 1.083 Å in Hirshfeld in comparison with 0.941/0.943 Å in X-ray).

Figure 8 Hirshfeld surface map generated step by step around two symmetry-independent mol­ecules of II. The two mol­ecules outside the surface were given to show the hydrogen-bond inter­actions with the mol­ecules within the surface. The red region labelled (i) is related to a close H⋯H contact between the mol­ecules within and outside the surface (not shown).

The contribution percentages of various contacts were obtained for the two symmetry-independent mol­ecules. Compared with I, the structure of II shows fewer H⋯O, H⋯C and O⋯C contacts (7.1%/7.0%, 26.1%/25.6%, 0.1% for both), which were compensated with remarkable H⋯H (64.2%/64.8%), and C⋯C contacts (2.5% for both). The smaller volume/Z ratio in II is reflected by the crowding, manifested in increased H⋯H contacts and the observation of C⋯C contacts.

6. Spectroscopy of I and II

In the IR spectra, the N—H stretching bands are centred at 3268 cm⁻¹ for I and 3152 cm⁻¹ for II. The lower NH stretching wave number of II is attributed to stronger N—H⋯OP hydrogen bonds as discussed in the X-ray crystallography section. The bands at 1244 cm⁻¹ for I and 1192 cm⁻¹ for II are assigned to the P=O vibrations, and the higher wave number for I is in accordance with the presence of more electronegative atoms in the (O)₂P(O)N skeleton [versus (C)₂P(O)N for II].

In the ¹³C NMR spectra, the doublet signals at 31.80 p.p.m. (³J = 8.1 Hz) for I and at 32.62 p.p.m. (³J = 4.7 Hz) for II correspond to the CH₂ group. The dissymmetric carbon atom does not show coupling with phospho­rus, and the ipso-C atom attached to it, i.e. with a three-bond separation from phospho­rus, shows a doublet at 143.04 p.p.m. (³J = 3.0 Hz) in I and at 145.50 p.p.m. (³J = 4.6 Hz) in II.

For the two diastereotopic C₆H₅O groups in I, two sets of carbon signals are observed. For example, the doublets at 150.74/150.92 p.p.m. and 120.12/120.23 p.p.m., with ²J = 7.0 Hz for the first pair and ³J = 4.0 Hz for the second pair, are associated with the diastereotopic ipso-C atoms and diastereotopic ortho-C atoms, respectively. All carbon atoms of diastereotopic phenyl groups in compound II show couplings with phospho­rus (¹J, ²J, ³J and ⁴J).

The doublet signals at 131.74/131.86 p.p.m. (J = 1.9/2.1 Hz) are assigned to the para-carbon atoms of the phenyl rings with four bonds separation from the phospho­rus atom. The doublets at 132.20/132.38 p.p.m. (J = 9.4/9.5 Hz) and at 128.62/128.82 p.p.m. (J = 12.2/12.1 Hz) are assigned to the diastereotopic ortho- and meta-carbon atoms. The doublets centred at 134.44 and 134.77 p.p.m. (J = 127.4 and 126.4 Hz) are related to the diastereotopic ipso-carbon atoms. The separation of these signals is comparable with previously investigated ¹J coupling constants for analogous compounds, typically in (C₆H₅)₂P(O)(NH-cyclo-C₇H₁₃) with ¹J = 129.4 Hz (Hamzehee et al., 2017).

A brief discussion of ³¹P NMR and ¹H NMR spectroscopy is given in the supporting information (Figures S2 to S11).

7. Conclusions

The differences/similarities of diastereotopic pairs, 2×C₆H₅O/2×C₆H₅, were discussed for two new single-enanti­omer structures, (C₆H₅O)₂P(O)[NH-(+)CH(C₂H₅)(C₆H₅)] (I), and (C₆H₅)₂P(O)[NH-(+)CH(C₂H₅)(C₆H₅)] (II). The pronounced differences are related to the contributions in the crystal packing by diastereotopic groups, especially in the C—H⋯π inter­actions, and the NMR chemical shifts of corresponding ¹³C signals. The geometry parameters, conformations and NMR coupling constants of diastereotopic groups show minor differences (and/or similarities in some cases). In I with the O₂P(O)N skeleton, the shorter P=O/P—N bonds and weaker N—H⋯O=P hydrogen bond are observed with respect to the structure II with the C₂P(O)N skeleton. These structural features, resulting from different electronegativities of atoms, are reflected in the higher stretching frequencies of P=O and N—H bonds in the structure I (the latter because of a weaker N—H⋯O=P hydrogen bond). The lower volume/Z ratio of II is reflected by the crowding and observation of C⋯C contacts and raising H⋯H contacts, while I includes more H⋯O and O⋯C contacts. The study of analogous chiral structures retrieved from the CSD shows minor differences in bond lengths for diastereotopic P—C, P—O, and P—N bonds and more significant differences in torsion angles of diastereotopic groups.

8. Synthesis and crystallization

Preparation of (C₆H₅O)₂P(O)[NH-(R)-(+)CH(C₂H₅)(C₆H₅)], (I). To a solution of (C₆H₅O)₂P(O)Cl in dry chloro­form, a solution of R-(+)-1-phenyl­propyl­amine and tri­ethyl­amine (1:1:1 molar ratio) in the same solvent was added at 273 K. After stirring for 4 h, the solvent was removed in a vacuum, and the obtained solid was washed with distilled water to remove (C₂H₅)₃NHCl. Colourless crystals were obtained from a solution of the title compound in CHCl₃/CH₃CN (1:2 v/v) after slow evaporation at room temperature.

Analytical data: IR (KBr, ν, cm⁻¹): 3268, 3063, 3029, 2970, 2929, 2854, 1592, 1492, 1453, 1420, 1244, 1200, 1167, 1058, 1020, 949, 900, 750, 689, 634, 579, 552, 520, 496, 457. ¹H NMR (400.22 MHz, CDCl₃): δ = 0.84 (t, J = 7.2 Hz, 3H), 1.81 (m, 2H), 3.84 (t, J = 10.8 Hz, 1H, NH), 4.32 (m, 1H), 6.99 (d, J = 8.4 Hz, 2H), 7.10 (t, J = 7.2 Hz, 1H), 7.16 – 7.35 (m, 12H); ¹³C{¹H} NMR (100.64 MHz, CDCl₃): δ = 10.59, 31.80 (d, J = 8.1 Hz), 58.20, 120.12 (d, J = 4.0 Hz), 120.23 (d, J = 4.0 Hz), 124.63, 124.83, 126.50, 127.21, 128.44, 129.43, 129.64, 143.04 (d, J = 3.0 Hz), 150.74 (d, J = 7.0 Hz), 150.92 (d, J = 7.0 Hz); ³¹P{¹H} NMR (162.01 MHz, CDCl₃): δ = −2.16.

Preparation of (C₆H₅)₂P(O)[NH-(R)-(+)CH(C₂H₅)(C₆H₅)], (II). To a solution of (C₆H₅)₂P(O)Cl in dry chloro­form, a solution of R-(+)-1-phenyl­propyl­amine and tri­ethyl­amine (1:1:1 mole ratio) in the same solvent was added at 273 K. After stirring for 4 h, the solvent was removed in a vacuum, and the obtained solid was washed with distilled water to remove (C₂H₅)₃NHCl. Colourless crystals were obtained from a solution of the title compound in CHCl₃/CH₃CN (1:2 v/v) after slow evaporation at room temperature.

Analytical data: IR (KBr, ν, cm⁻¹): 3152, 3057, 3027, 2962, 2928, 2868, 1488, 1440, 1383, 1337, 1305, 1192, 1117, 1056, 1017, 929, 904, 838, 751, 721, 695, 603, 564, 533. ¹H NMR (400.22 MHz, DMSO-d₆): δ = 0.79 (t, J = 7.6 Hz, 3H), 1.69 (m, 1H), 1.82 (m, 1H), 3.84 (m, 1H), 5.91 (t, J = 10.2 Hz, 1H, NH), 7.26 (m, 5H), 7.37 (m, 2H), 7.50 (m, 4H), 7.64 (m, 2H), 7.79 (m, 2H); ¹³C{¹H} NMR (100.64 MHz, DMSO-d₆): δ = 11.60, 32.62 (d, J = 4.7 Hz), 57.10, 126.87, 126.97, 128.45, 128.62 (d, J = 12.2 Hz), 128.82 (d, J = 12.1 Hz), 131.74 (d, J = 1.9 Hz), 131.86 (d, J = 2.1 Hz), 132.20 (d, J = 9.4 Hz), 132.38 (d, J = 9.5 Hz), 134.44 (d, J = 127.4 Hz), 134.77 (d, J = 126.4 Hz), 145.50 (d, J = 4.6 Hz); ³¹P{¹H} NMR (162.01 MHz, DMSO-d₆): δ = 21.13.

9. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 5. The H atoms were all located in difference-Fourier maps, but those attached to C atoms were repositioned geometrically. The H atoms were initially refined with soft restraints on the bond lengths and angles to regularize their geometries (C—H in the range 0.93–0.98 Å, N—H in the range 0.86–0.89 Å) and U_iso(H) values in the range 1.2–1.5×U_eq of the parent atom, after which the positions were refined with riding constraints (Cooper et al., 2010; Watkin & Cooper, 2016). The absolute configuration was determined from the refinement of the Flack parameter (Parsons et al., 2013).

Table 5 Experimental details   I II Crystal data Chemical formula C21H22NO3P C21H22NOP Mr 367.38 335.39 Crystal system, space group Orthorhombic, P212121 Triclinic, P1 Temperature (K) 120 95 a, b, c (Å) 5.4947 (1), 8.1503 (1), 41.1096 (7) 9.0483 (7), 10.5533 (8), 11.0036 (6) α, β, γ (°) 90, 90, 90 70.065 (6), 86.368 (5), 66.571 (7) V (Å3) 1841.03 (5) 903.15 (13) Z 4 2 Radiation type Cu Kα Cu Kα μ (mm−1) 1.49 1.39 Crystal size (mm) 0.90 × 0.27 × 0.07 0.62 × 0.09 × 0.07   Data collection Diffractometer Oxford Diffraction Gemini Oxford Diffraction SuperNova Absorption correction Multi-scan (CrysAlis PRO; Rigaku OD, 2017) Multi-scan (CrysAlis PRO; Rigaku OD, 2017) Tmin, Tmax 0.34, 0.90 0.49, 0.91 No. of measured, independent and observed [I > 2.0σ(I)] reflections 34246, 3356, 3262 15035, 6781, 6648 Rint 0.067 0.036 (sin θ/λ)max (Å−1) 0.626 0.626   Refinement R[F > 2σ(F)], wR(F), S 0.037, 0.102, 1.02 0.034, 0.092, 0.97 No. of reflections 3355 6779 No. of parameters 240 443 No. of restraints 4 11 H-atom treatment H atoms treated by a mixture of independent and constrained refinement H atoms treated by a mixture of independent and constrained refinement Δρmax, Δρmin (e Å−3) 0.33, −0.38 0.49, −0.40 Absolute structure Parsons et al. (2013), 1324 Friedel pairs Parsons et al. (2013), 3140 Friedel pairs Absolute structure parameter 0.013 (9) −0.013 (7) Computer programs: CrysAlis PRO (Rigaku OD, 2017), SUPERFLIP (Palatinus & Chapuis, 2007), CRYSTALS (Betteridge et al., 2003), JANA2006 (Petříček et al., 2014), Mercury (Macrae et al., 2020) and MCE (Rohlíček & Hušák, 2007).