Low-dimensional coordination polymeric structures in alkali metal complex salts of the herbicide (2,4-di­chloro­phen­oxy)acetic acid (2,4-D)

The ring-substituted phen­oxy­alkanoic acids comprise an important group of chemical reagents having selective herbicidal properties which have resulted in their commercial utilization (Cobb & Reade, 2011). Of these, 2-(2,4-di­chloro­phen­oxy)­acetic acid (2,4-D) is considered one of the most prominent members (O'Neil, 2001). It also provides features which make it a good candidate for metal complex formation in having as an anion, along with the carboxyl­ate group, a stereochemically favourable phen­oxy O atom for potential chelate formation. Considering these factors, it is not surprising that 2,4-D has been combined with a wide range of metal types and the resulting characterized complex examples amount to more than 50 entries in the CSD (Groom & Allen, 2014). These include a number of mixed-ligand and mixed-metal complexes. However, there are only two examples of alkalai metal complex salts with 2,4-D, viz. (i) the hemihydrate potassium salt (Kennard et al., 1983), which forms a two-dimensional coordination polymeric complex structure, and (ii) the caesium complex salt with hydrogen bis­(2,4-di­chloro­phen­oxy)­acetate (Smith & Lynch, 2014). This second mentioned ligand species is analogous to the ligand in sodium hydrogen bis­(phen­oxy­acetate) (Evans et al., 2001a), as well as the hydrogen bis­(4-nitro­benzoate) species found in the early reported potassium salt (Srivastava & Speakman, 1961) and in the rubidium salts of hydrogen bis­(acetyl­salicylate) (Grimvall & Wengelin, 1967) and the isostructural rubidium hydrogen bis­(3-chloro­benzoate) and rubidium hydrogen bis­(3-bromo­benzoate) salts (Van Deun et al., 2005).

The structures of the salts of the alkali metals other than lithium with the phen­oxy­acetic acid analogues are generally not numerous in the crystallographic literature, comprising five other examples besides those previously mentioned for 2,4-D, i.e. sodium phen­oxy­acetate hemihydrate (Prout et al., 1971; Evans et al., 2001b), caesium phen­oxy­acetate (Smith, 2014), caesium (4-fluoro­phen­oxy)­acetate, caesium (4-chloro-2-methyl­phen­oxy)­acetate (Smith & Lynch, 2014) and caesium o-(phenyl­ene­dioxy)­diacetate dihydrate (Smith et al., 1989). With lithium, the structures of three complexes are known, i.e. with (2-chloro­phen­oxy)­acetic acid (O'Reilly et al., 1987), (2-carbamolyphen­oxy)­acetic acid (Mak et al., 1986) and o-(phenyl­ene­dioxy)­diacetic acid (Smith et al., 1986). These Li⁺ complexes, as with most lithium carboxyl­ates, have predominantly basic tetra­hedral LiO₄ coordination geometry in polymeric structures, e.g. [LiO₄]_n in anhydrous lithium 3,5-di­nitro­benzoate (Yang & Ng, 2007) or [LiO₂(H₂O)₂]_n in lithium salicylate (Wiesbrock & Schmidbaur, 2003).

In the structures of the alkali metal phen­oxy­acetates are found examples of both the bidentate chelate (O,O')_carb­oxy, and (O,O¹)_{carb­oxy/phen­oxy} metal–ligand inter­actions, forming sheet substructures. With the potassium–2,4-D salt (Kennard et al., 1983), a third characteristically phen­oxy bidentate chelate inter­action is found which involves a K—Cl bond to the ortho-Cl ring substituent of the ligand, generating an eight-membered chelate ring about K.

To investigate the modes of inter­action and the nature of the coordination complex structures found in the alkali metal compounds with 2,4-D, the salts with Li⁺, Na⁺, Rb⁺ and Cs⁺ were prepared and crystals of three of these (the Li⁺, Rb⁺ and Cs⁺ salts) were determined and the structures are reported herein. These are the trihydrate {[Li(2,4-D)(H₂O)].2H₂O}_n, (I), and the hemihydrates [Rb₂(2,4-D)₂(H₂O)]_n, (II), and [Cs₂(2,4-D)₂(H₂O)]_n, (III). With the previously reported structure of the Cs complex salt with hydrogen bis­[(2,4-di­chloro­phen­oxy)­acetate] (Smith & Lynch, 2014), the preparation involved the reaction of 2,4-D with CsCl, unlike our more usual preparations using CsOH, as was the case in the preparation of (III). Suitable crystals of the Na–2,4-D analogue could not be obtained.

The title compounds (I)–(III) were synthesized by heating together for 10 min, 1:1 stoichiometric qu­anti­ties of 2-(2,4-di­chloro­phen­oxy)­acetic acid (1.0 mmol, 220 mg) and, respectively, LiOH (1.0 mmol, 24 mg), Rb₂CO₃ (0.5 mmol, 125 mg) or CsOH (1.0 mmol, 150 mg), in an ethanol–water mixture (15 ml, 1:9 v/v). Partial room-temperature evaporation of the solutions gave in all cases, colourless crystal plates from which specimens were cleaved for the X-ray analyses. Crystals of (I) was found to be unstable in air, apparently losing water molecules of solvation.

Crystal data, data collection and structure refinement details are summarized in Table 1. Crystal data, data collection and structure refinement details are summarized in Table 1. H atoms were placed in calculated positions (aromatic C—H = 0.95 Å and methyl­ene C—H = 0.99 Å) and were allowed to ride in the refinements, with U_iso(H) = 1.2U_eq(C). The water H atoms were located in difference Fourier maps. Their positions were refined, but for (I) and (III) the O—H and H···H distances were restrained to 0.88 (2) and 1.40 (4) Å, respectively, whilst for (II), the O—H distances were restrained to 0.90 (2) Å. For all water H atoms, U_iso(H) = 1.5U_eq(O). With (III), although of no significance in this achiral structure, the Flack absolute structure factor (Flack, 1983) was determined as 0.001 (16) for 2851 Friedel pairs.

All three structures, i.e. (I)–(III), give low-dimensional coordination polymers in which the core substructures comprise the metal–oxygen coordination chains or sheets with the aromatic rings of the ligands peripherally located between them. However, there are no inter-ring π–π inter­actions in any of the structures [minimun ring-centroid separations = 4.747 (1) Å in (I), 4.359 (15) Å in (II) and 5.640 (3) Å in (III)].

In the structure of the trihydrate Li⁺ salt with 2,4-D, (I), the asymmetric unit (Fig. 1) comprises the common slightly distorted tetra­hedral LiO₄ coordination unit [Li—O range = 1.931 (3)–1.986 (3) Å] and two water molecules of solvation (O2W and O3W). The coordination unit comprises one monodentate carboxyl­ate O-atom donor (O13) and a water molecule (O1W), while there are two bridging carboxyl­ate O-atom donors [O14ⁱ and O14ⁱⁱ[ symmetry codes: (i) x, y-1, z; (ii) -x+3/2, y-1/2, -z+3/2]. Conjoined six-membered ring systems in which the Li···Li separation is 3.045 (4) Å generate a one-dimensional coordination polymeric chain substructure which extends along b (Figs. 2 and 3). Hydrogen bonding involving both the coordinated and solvent water molecules and both carboxyl­ate and phen­oxy O-atom acceptors, as well as water–water inter­actions (Table 2), give an overall two-dimensional structure which lies parallel to (001) (Fig. 3).

The 2,4-D ligand has the synclinal phen­oxy­acetate side-chain conformation [defining torsion angle (about O11–C12) = 90±30°], with torsion angles C2—C1—O11—C12 = -171.51 (13)°, C1—O11—C12—O13 = 72.75 (17)° and O11—C12—C13—O14 = -174.58 (14)°, similar to that found in the parent acid (2,4-D), where the comparative defining value is 75.2° (Smith et al., 1976).

The hemihydrate Rb⁺ salt with 2,4-D, (II) (Fig. 4), comprises an RbO₅Cl complex unit with the bridging coordinated water molecule (O1W) lying on a crystallographic twofold rotation axis. In the very distorted o­cta­hedral coordination sphere about Rb1 [Rb—O range = 2.7909 (16)–2.946 (2) Å] (Table 3), an example of the bidentate chelate phen­oxy-Cl ligand–metal inter­action is found, involving a carboxyl­ate O13 donor and the ortho-related Cl ring-substitutuent (Cl2). This type of inter­action has no precedence in Rb–phen­oxy complex structures, but is similar to that found in the Cs–2,4-D structure (III) where the inter­mediate phen­oxy atom O11 is sufficiently close to the Cs to be considered coordinating, giving a tridentate inter­action. However, with (II), this Rb1···O11 distance [3.2789 (19) Å] is beyond an acceptable Rb—O bond range. Carboxyl­ate atoms O13 and O14 are also bridging, as is the coordinated water molecule (O1W) on the twofold axis, giving two-dimensional layers which lie parallel to (100) (Figs. 5 and 6). Within the polymer layers, the minimum Rb1···Rb1 ⁱⁱ separation is 4.3312 (5) Å within a centrosymmetric four-membered Rb₂O₂ ring. The water molecule is also involved in intra­layer O—H···O_{carboxyl­ate} hydrogen-bonding inter­actions (Table 4). The 2,4-D ligand adopts the anti­periplanar (torsion angle 180±30°) conformation, with the defining C1—O11—C12—C13 torsion angle of 173.03 (19)°.

It is of inter­est that the two-dimensional structures of the potassium 2,4-D salt (Kennard et al., 1983) (a hemihydrate with the bridging water molecule on a twofold axis), is similar in all respects to the structure of (II) and crystallizes with Z = 8 (space group C2/c) in an isomorphous cell with that of (II) [for K–2,4-D: a = 36.80 (1), b = 4.339 (1), c = 12.975 (7) Å, β = 102.03 (4)° and V = 2026 ų]. This similarity also extends to the two-dimensional ammonium 2,4-D hemihydrate structure (Liu et al., 2009), with crystals having a = 37.338 (8), b = 4.388 (9), c = 12.900 (3) Å, β = 103.82 (3)°, V = 2074.7 (8) ų and Z = 8, with space group C2/c. In this structure, the ammonium cation occupies an equivalent site to the Rb cation in the structure of (II), with the water molecule similarly on the twofold axis and forming intra­layer hydrogen bonds with the O14 carboxyl­ate O-atom acceptors of related 2,4-D anions.

For the Cs⁺ salt with 2,4-D, (III), the asymmetric unit comprises two irregular CsO₆Cl complex units (A and B), with the water molecule (O1W) bridging (Fig. 7). Each unit has identical donor components, i.e. two anion O atoms (carboxyl­ate O13A/B and phen­oxy O11A/B) and an ortho-substituted ring Cl-donor (Cl2A/B), in a tridentate chelate mode; two bridging carboxyl­ate O-atom donors (O13A/B and O14A/B) and the bridging water molecule. This 2,4-D coordination mode with the elongated Cs—Cl bond [3.6446 (16) (A) and 3.5146 (16) Å (B)] was also found in the Cs hydrogen bis­[(2,4-di­chloro­phen­oxy)­acetate complex species [Cs—Cl = 3.6035 (14) Å; Smith & Lynch, 2014]. However, in (III), there is a major conformational difference between ligands A and B, one having the anti­periplanar phen­oxy­acetate side-chain conformation [torsion angles C2A—C1A—O11A—O12A = -174.3 (4)°, C1A—O11A—C12A—O13A = 169.2 (4)° and O11A—C12A—C13A—O14A = 154.3 (4)°], comparing with the comparative angles in the B ligand [153.2 (5), -72.5 (5) and 155.7 (4)°], where the mid-angle is synclinal. This B-ligand conformation is quite similar to that of the parent acid (torsion angle = 75.2°; Smith et al., 1976), which is an unusual member of the phen­oxy­acetate acid series where the side-chain conformation is predominantly anti­periplanar (Lynch et al., 1999). The Cs—O11A/B bond lengths within the tridentate chelate ligand [3.331 (4) (A) and 3.423 (4) Å (B)] are longer than what is normally considered a typical Cs—O bond length, with the range for the other Cs—O bonds in (III) being 2.945 (4)–3.360 (4) Å (Table 5).

In the crystal, the bridging O and Cl atoms give a series of cyclic inter­actions resulting in an overall two-dimensional sheet structure which lies parallel to (001) (Figs. 8 and 9). Within this structure there are a number of conjoined cyclic inter­actions, including a Cs₂O₂ example in which the minimum Cs1···Cs2ⁱ separation is 4.4463 (5) Å. The coordinated water molecule provides intra­layer O—H···O hydrogen bonds to carboxyl­ate O-atom acceptors O14Aⁱ and O14Bⁱⁱ (Table 6).

The presence of coordinated ring-substituted Cl donors such as those found in (III) has precedence in two Cs⁺ complexes with aromatic carb­oxy­lic acids, viz. 4-amino-3,5,6-tri­chloro­pyridine-2-carb­oxy­lic acid [Cs—Cl = 3.6052 (11)–3.7151 (11) Å; Smith, 2013a] and 2,3-6-tri­chloro­phenyl­acetic acid [Cs—Cl = 3.646 (2) and 3.711 (2) Å; Smith, 2013b].

The present set of structures of the alkali metal salts of 2-(2,4-di­chloro­phen­oxy)­acetic acid show a trend common with phen­oxy­acetic acids for formation of two-dimensional polymers with an incidence of both O,O' and O,O¹-chelates and with Rb and Cs, formation of the uniquely phen­oxy bidentate (Rb) or tridentate (Cs) Cl,O,O¹-chelate inter­actions.