1,7-Di­hydro-1,4,7,10-tetra­aza­cyclo­­dodecane­phosphine oxide iodide

Cyclen chemistry is extensive with 431 hits in the November 2002 issue of the Cambridge Structural Database (CSD; Allen, 2002). However, only one cyclen phosphine oxide is described in the database, namely cyclenphosphine oxide dihydrate, (II) (Oget et al., 1999). Compound (II) was first described in a patent (Richman, 1976) and the solution structure elucidated by NMR methods (Richman & Kubale, 1983). Although other cyclen phosphine chalcogenide derivatives have been synthesized (Oget et al., 1998), no structural information has been reported.

Compound (I) is a hydrolytic by-product formed during reactions of cyclenphosphorane (Gupta et al., 1998). The title compound, (I), is similar to (II). (I) is protonated, cationic and charge balanced by an iodide anion (see Fig. 1). The P atom lies on a special position and the other half of the molecule is symmetry generated. The P atom is five-coordinate and forms a slightly distorted trigonal bipyramid (tbp). The equatorial plane [N2, O1, N2ⁱ and P1; symmtery code: (i) 1/3 + x-y, 2/3 − y, 5/3 − z] is planar, with the sum of the angles around P1 equal to 360°. The distortion from tbp can be seen in the axial and equatorial N—P—N angles [167.1 (3), 123.4 (4) and 118.3 (2)°]. The P—N distances show that the equatorial N atoms are bonded to the phosphorus [P1—N2 and P1—N2ⁱ = 1.656 (5) Å]. The apical P—N distances [P1—N1 and P1—Niⁱ = 1.891 (4) Å] are longer than a single P—N bond. They are considerably shorter than the sum of the van der Waals radii (3.35 Å) and indicate a strong coordination by these N atoms to the central phosphorus. The elongation of the apical P—N bond in a tbp is expected and this bond lengthening has been reported previously with a range of P—N_apical distances of 1.8 to 2.11 Å [e.g. CSD refcode YAFDUE (Khasnis et al., 1992), LOBYUW (Gupta et al., 1999) and GOCPUJ (Oget at al., 1999)]. Atoms N1 and N1ⁱ are both protonated and the H atom was located on the difference map. The I atom is site shared in the asymmetric unit in two distinct special positions, with occupancies of 1/6 for I1 and 1/3 for I1'. I1 is located at Wyckoff position b (multiplicity 3) at full occupancy. I1' is located at position d (multiplicity 9) at 0.6667 of full occupancy for charge balance, and in keeping with the refined occupancy (0.16666 for I1 and 0.3333 for I1').

The cyclen phosphine oxide moiety is twisted along the N1—P1—N1ⁱ plane. The amido H atoms are oriented to either side of this plane (0.41 and −0.41 Å). This produces a slight helical distortion of the cyclen moiety. This helical distortion can also be seen in bis(borane)cyclenphosphorane (Dupart et al., 1985). The absolute configuration of chiral (I) could not be determined reliably and (I) was refined as a racemic mixture.

The extended solid state structure generated by intermolecular interactions presents an interesting picture:

(i) N—H···O hydrogen bonding. There are two of these interactions per cyclen moiety. They link the cyclen PO units into a spiral chain that runs parallel to [001]. This is shown in Figs. 2(a) and 2(b). Distances and angles are given in Table 1.

(ii) C—H···I interactions. These `interactions' should be considered extremely weak or almost non-existant. They are at the furthest limit of reported weak C—H···X interactions (Desiraju & Steiner, 2001). However, they may have an influence on the supramolecular association by linking the spiral cyclen chains into a pseudo-hexagonal array (three H₂cyclenPO cations and three I⁻ anions) which is shown in Fig. 3. The space between these networked molecules are occupied by the symmetry related unassociated iodine position. This leaves large voids between the spiral chains, ca 94 ų in the asymmetric unit.