1. Chemical context

Hetero­allylic N,N′-chelating donor ligands such as amidinate anions [RC(NR)₂]⁻ and guanidinate anions [R₂NC(NR)₂]⁻ are of significant importance in various fields of organometallic and coordination chemistry. It is generally accepted that both types of N,N′-chelating ligands can be regarded as `steric cyclo­penta­dienyl equivalents' (Bailey & Pace, 2001; Collins, 2011; Edelmann, 2013). Over the past three decades, amidinato and guanidinato complexes have been synthesized for nearly every metallic element in the Periodic Table ranging from lithium to the f-block elements (Edelmann, 2009, 2012, 2013; Trifonov, 2010). Important applications of amidinate and guanidinate ligands include the stabilization of unusually low oxidation states (e.g. Mg^I and Fe^I) as well as the design of highly active homogeneous catalysts (Collins, 2011; Edelmann, 2013; Chen et al., 2018). Metal amidinate and guanidinate complexes bearing small aliphatic substituents have also been established as ALD (= atomic layer deposition) and MOCVD (= metal–organic chemical vapor deposition) precursors for the deposition of thin films of metals, metal oxides, metal nitrides etc. (Devi, 2013). Formally, amidinate anions are nitro­gen analogues of carboxyl­ate anions, while guanidinates are related in the same way to carbamate anions. However, in contrast to the carboxyl­ates and carbamates, the steric properties of amidinates and guanidinates can be tuned over a wide range by employing different substituents at the outer nitro­gen atoms as well as at the central carbon atom of the chelating NCN unit. The most important starting materials in this area are lithium amidinates, which are normally prepared in a straightforward manner by the addition of lithium alkyls to N,N′-diorganocarbodi­imides in a 1:1 molar ratio. Lithium guanidinates are formed in the same manner by adding lithium-N,N-di­alkyl­amides to N,N′-diorganocarbodi­imides (Stalke et al., 1992; Aharonovich et al., 2008; Chlupatý et al., 2011; Nevoralová et al., 2013; Hong et al., 2013). All of these reactions are generally quite straightforward and afford the desired products in high yields. Less investigated are amidin­ate salts of the heavier alkali metals sodium and potassium (Cole et al., 2003; Cole & Junk, 2003; Junk & Cole, 2007; Yao et al., 2009; Dröse et al., 2010, Chen et al., 2018).

We recently reported in this journal that, under certain conditions, seemingly straightforward reactions of lithium alkyls with N,N′-diorganocarbodi­imides can take a different course, leading to lithium salts of dimerized amidinates ligands (`amidino­guanidinates') (Sroor et al., 2016). These could even become the major reaction products when the N,N′-diorg­ano­carbodi­imides are used in a twofold molar excess. The first complexes comprising amidino­guanidinate ligands included the lithium precursors Li[ⁿBuC(=NR)(NR)C(NR)₂] [R = ⁱPr, Cy (= cyclo­hex­yl)] and the holmium(III) complex [ⁿBuC(=NCy)(NCy)C(NCy)₂]Ho[ⁿBuC(NCy)₂](μ-Cl)₂Li(THF)₂ (Sroor et al., 2016). In this contribution, we report the synthesis and structural characterization of the first potassium amidino­guanidinate derivative, polymeric catena-poly[[bis­(μ-1-amidinato-N,N′,N′′,N′′′-tetra­iso­propyl­guanidinato-κ⁵N¹:N¹,N²:N²,N⁴)dipotassium]-μ-1,2-di­meth­oxy­ethane-κ²O:O′] [{ⁱPrN=CHN(ⁱPr)N(NⁱPr)₂K}₂(μ-DME)]_n.

As illustrated in Fig. 1, the title compound was formed when N,N′-diiso­propyl­carbodi­imide was added to a suspension of potassium hydride in 1,2-di­meth­oxy­ethane (DME). With the attempt to prepare the corresponding amidinate K[HC(NⁱPr)₂], the reactants were used in a molar ratio 1:1. After filtration and concentration of the filtrate to a small volume, the product crystallized directly at room temperature and could be isolated as colorless, plate-like, moisture-sensitive crystals in 76% yield (calculated after determination of the crystal structure). The compound was characterized through elemental analysis as well as IR, NMR (¹H and ¹³C) and mass spectra. However, the usual set of analytical and spectroscopic methods did not allow for an unequivocal elucidation of the mol­ecular structure. NMR data clearly indicated the presence of coordinated DME. However, both the ¹H and ¹³C NMR spectra showed two sets of iso-propyl resonances, thereby ruling out the formation of a simple potassium formamidinate salt of the composition `(DME)K[HC(NⁱPr)₂]'. Fortunately, the single crystals obtained directly from the filtered and concentrated reaction solution were suitable for X-ray diffraction analysis. This study confirmed the formation of a new amidino­guanidinate complex through dimerization of N,N′-diiso­propyl­carbodi­imide in the coordination sphere of potassium.

Figure 1 Formation of the title compound by reaction of potassium hydride with N,N′-diiso­propyl­carbodi­imide in DME.

2. Structural commentary

The mol­ecular structure of the title compound consists of centrosymmetric dimeric units, being composed of two potassium atoms and two amidino­guanidinate ligands (Fig. 2). The guanidinate unit is attached to potassium in an N,N′-chelating mode, with the K atom in the N₃C plane of the guanidinate. The same guanidinate moiety is linked to the symmetry-equivalent K atom in an η³-di­aza­allyl mode, i.e. the metal atom is situated above the N1/C1/N2 plane. The exposed nitro­gen donor of the amidinate backbone (N4) in the title compound is attached to the metal center in a simple monodentate coordination, with the N atom having a perfectly planar environment (sum of bond angles = 360.0°). This is in agreement with the expected sp² hybridization of atom N4 (cf. Scheme). As a result of the μ-bridging coordination of the amidino­guanidinate ligand, the potassium atom is surrounded by a σ-chelating guanidinate group, a π-di­aza­allyl-coordinated guanidinate group, and a single amidinate nitro­gen atom in a T-shaped fashion. A pseudo-square-planar coordination is completed by one oxygen atom of a μ-κO:κO′-coordinated DME ligand. Through this bridging DME coordination, the dimeric units are inter­connected into a one-dimensional coordination polymer (Fig. 3).

Figure 2 Mol­ecular structure of the title compound in the crystal. Displacement ellipsoids are drawn at the 50% probability level, hydrogen atoms omitted for clarity. Symmetry codes: (′) −x, −y, 2 − z; (′′) −x, −1 − y, 2 − z.

Figure 3 Illustration of the polymeric chain structure of the title compound, extending along the crystallographic b axis.

An increased tendency towards π-coordination modes is characteristic for the heavier alkali metals and has frequently been observed in other complexes with nitro­gen ligands (e.g. von Bülow et al., 2004; Liebing & Merzweiler, 2015). However, in potassium amidinates and guanidinates, a symmetric double-chelating coordination is usually preferred over coordination modes with a contribution of the π-electron system (Fig. 4) (Giesbrecht et al., 1999; Benndorf et al., 2011). A similar mixed σ-/π-coordination to that in the title compound has been recently observed by us in a potassium di­thio­carbamate (Liebing, 2017).

Figure 4 Coordination modes of 1,3-di­aza­allyl-type ligands (= amidinate or guanidinate) observed in potassium complexes: symmetric double-chelating (A), single-chelating and η3-coordination of the 1,3-di­aza­allyl π-system (B).

The K—N bond lengths to the σ-bonded guanidinate group are 2.793 (2) Å (N1) and 2.814 (2) Å (N2), while the bond to the single amidinate nitro­gen donor (N4) is considerably longer at 2.939 (2) Å. All these values are within the range usually observed for K—N bonds (crystal structures deposited in the CSD; Groom et al., 2016). The K—N distances to the π-coordinated guanidinate group are 2.882 (2) Å (N1) and 2.979 (2) Å (N2), and the corresponding K—C1 separation was determined to be 2.967 (2) Å. The latter value is considerably smaller than in a structurally related potassium di­thio­carbamate [K—C 3.150 (2) Å; Liebing, 2017].

3. Supra­molecular features

The crystal structure of the title compound does not display any specific inter­actions between the polymeric chains. The closest inter­chain contact is 3.632 (3) Å (C5⋯C14) between the methyl carbon atoms of isopropyl groups.

4. Database survey

For a review article on related alkali metal bis­(ar­yl)formamidinates, see: Junk & Cole (2007). For other structurally characterized alkali metal amidinates and guanidinates, see: Giesbrecht et al. (1999), Stalke et al. (1992), Cole et al. (2003), Aharonovich et al. (2008), Chlupatý et al. (2011), Cole & Junk (2003), Junk & Cole (2007), Benndorf et al. (2011), Nevoralová et al. (2013) and Hong et al. (2013).

5. Synthesis and crystallization

General Procedures: The reaction was carried out under an inert atmosphere of dry argon employing standard Schlenk and glove-box techniques. The solvent di­meth­oxy­ethane (DME) was distilled from sodium/benzo­phenone under nitro­gen atmosphere prior to use. All glassware was oven-dried at 393 K for at least 24 h, assembled while hot, and cooled under high vacuum prior to use. The starting material N,N′-diiso­propyl­carbodi­imide was obtained from Sigma–Aldrich and used as received. Commercially available potassium hydride was freed from protecting paraffin oil by thoroughly washing with n-pentane and stored in a glove-box. The ¹H and ¹³C NMR spectra were recorded in solutions on a Bruker Biospin AVIII 400 MHz spectrometer at 298 K. Chemical shifts are referenced to tetra­methyl­silane. The IR spectrum was measured with a Bruker Optics VERTEX 70v spectrometer, and the electron impact mass spectrum was recorded using a MAT95 spectrometer with an ionization energy of 70 eV. Microanalysis of the title compound was performed using a `vario EL cube' apparatus from Elementar Analysensysteme GmbH. The melting/decomposition point was measured on a Büchi Melting Point B-540 apparatus.

Synthesis of [{ⁱPrN=CHN(ⁱPr)N(NⁱPr)₂K}₂(μ-DME)]_n: 1.6 mL (1.26 g, 10.0 mmol) of N,N′-diiso­propyl­carbodi­imide were added to a stirred suspension of 0.41 g (10 mmol) of KH in 50 ml of DME. The reaction mixture was stirred for two days and refluxed for an additional 2 h. After cooling to room temperature, all insoluble solid parts were filtered off and the volume of the resulting clear solution was reduced to ca 25 ml. After three days at room temperature, the title compound crystallized as colorless, plate-like crystals suitable for single-crystal X-ray diffraction. Yield: 1.3 g (76%). M.p. 378 K (dec.). C₃₂H₆₈K₂N₈O₂ (M = 675.15 g mol⁻¹): calculated C 56.93, H 10.15, N 16.60; found: C 56.81, H 10.24, N 16.33%. IR (ATR): ν = 2952 m, 2858 m, 2824 w, 1626 m, 1538 s, 1465 m, 1453 m, 1383 m, 1369 m, 1358 m, 1343 m, 1318 m, 1298 m, 1196 m, 1162 m, 1125 m, 1111 m 1048 w, 993 m, 955 w, 946 w, 858 w, 815 w, 674 w, 575 w, 516 w, 442 m 373 w, 338 m, 295 w, 262 m cm⁻¹. ¹H NMR (400.1 MHz, THF-d₈, 293 K): δ = 7.90 (s, 2H, N—CH=N), 3.47 [sept, 4H, CH(CH₃)₂], 3.43 (s, 8H, DME), 3.27 (s, 12H, DME), 3.01 [sept, 4H, CH(CH₃)₂], 1.15 [d, 24H, CH(CH₃)₂], 0.94 [d, 24H, CH(CH₃)₂] ppm. ¹³C NMR (100.6 MHz, THF-d₈, 293 K): δ = 166.0 (N—CH=N), 150.0 (N—CN—N), 72.6 (DME), 58.9 (DME), 55.5 [CH(CH₃)₂], 49.4 [CH(CH₃)₂], 28.2 [CH(CH₃)₂], 25.0 [CH(CH₃)₂] ppm. MS (EI, 70 eV): m/z = 254 (5) [C₁₄H₃₀N₄]⁺, 211 (30) [C₁₄H₃₀N₄ − ⁱPr]⁺, 184 (32), 170 (38), 144 (82), 129 (100).

6. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 1. H atoms attached to C atoms were fixed geometrically and refined using a riding model. CH₃ groups were allowed to rotate freely around the C—C vector, and the corresponding C—H distances were constrained to 0.98 Å. C—H distances within CH₂ groups were constrained to 0.99 Å, C—H distances within the ⁱPr CH groups to 1.00 Å, and the C—H distance within the amidinate group (i.e. at C2) to 0.95 Å. The U_iso(H) values were set at 1.5U_eq(C) for methyl groups and at 1.2U_eq(C) in all other cases. The reflections (001) and (010) disagreed strongly with the structural model and were therefore omitted from the refinement.

Table 1 Experimental details Crystal data Chemical formula [K2(C14H32N4)2(C4H10O2)] Mr 337.57 Crystal system, space group Triclinic, P Temperature (K) 153 a, b, c (Å) 10.3207 (6), 10.5311 (6), 11.6703 (7) α, β, γ (°) 71.605 (4), 64.168 (4), 63.516 (4) V (Å3) 1010.23 (11) Z 2 Radiation type Mo Kα μ (mm−1) 0.27 Crystal size (mm) 0.46 × 0.37 × 0.16   Data collection Diffractometer STOE IPDS 2T No. of measured, independent and observed [I > 2σ(I)] reflections 9148, 3941, 3368 Rint 0.104 (sin θ/λ)max (Å−1) 0.617   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.051, 0.139, 1.03 No. of reflections 3941 No. of parameters 208 H-atom treatment H-atom parameters constrained Δρmax, Δρmin (e Å−3) 0.41, −0.68 Computer programs: X-AREA and X-RED (Stoe & Cie, 2002), SIR97 (Altomare et al., 1999), SHELXL2018/3 (Sheldrick, 2015), DIAMOND (Brandenburg, 1999) and publCIF (Westrip, 2010).