Fe₄(OAc)₁₀[EMIM]₂: Novel Iron-Based Acetate EMIM Ionic Compound

We synthesized and characterized a novel iron(II) aceto EMIM coordination compound, which has a simplified empirical formula Fe₄(OAc)₁₀[EMIM]₂, in two different hydration forms: as anhydrous monoclinic compound and triclinic dihydrate Fe₄(OAc)₁₀[EMIM]₂·2H₂O. The dihydrate compound is isostructural with recently reported Mn₄(OAc)₁₀[EMIM]₂·2H₂O, while the anhydrate is a superstructure of the Mn counterpart, suggesting the existence of solid solutions. Both new Fe compounds contain chains of Fe²⁺ octahedrally coordinated exclusively by acetate groups. The EMIM moieties do not interact directly with the Fe²⁺ and contribute to the structural framework of the compound through van der Waals forces and C-H···O hydrogen bonds with the acetate anions. The compounds have a melting temperature of ∼94 °C; therefore, they can be considered metal-containing ionic liquids. Differential thermal analysis indicates three endothermic transitions associated with melting, structural rearrangement in the molten state at about 157 °C, and finally, thermal decomposition of the Fe₄(OAc)₁₀[EMIM]₂. Thermogravimetric analyses indicate an ∼72 wt % mass loss during the decomposition at 280-325 °C. The Fe₄(OAc)₁₀[EMIM]₂ compounds have higher thermal stability than their Mn counterparts and [EMIM][OAc] but lower compared to iron(II) acetate. Temperature-programmed desorption coupled with mass spectrometry shows that the decomposition pathway of the Fe₄(OAc)₁₀[EMIM]₂ involves four distinct regimes with peak temperatures at 88, 200, 267, and 345 °C. The main species observed in the decomposition of the compound are CH₃, H₂O, N₂, CO, OC-CH₃, OH-CO, H₃C-CO-CH₃, and H₃C-O-CO-CH₃. Variable-temperature infrared vibrational spectroscopy indicates that the phase transition at 160-180 °C is associated with a reorientation of the acetate ions, which may lead to a lower interaction with the [EMIM]⁺ before the decomposition of the Fe₄(OAc)₁₀[EMIM]₂ upon further heating. The Fe₄(OAc)₁₀[EMIM]₂ compounds are porous, plausibly capable of accommodating other types of molecules.