Manganese borohydride; synthesis and characterization

Abstract

Solvent-based synthesis and characterization of α-Mn(BH₄)₂ and a new nanoporous polymorph of manganese borohydride, γ-Mn(BH₄)₂, via a new solvate precursor, Mn(BH₄)₂·1/2S(CH₃)₂, is presented. Manganese chloride is reacted with lithium borohydride in a toluene/dimethylsulfide mixture at room temperature, which yields halide and solvent-free manganese borohydride after extraction with dimethylsulfide (DMS) and subsequent removal of residual solvent. This work constitutes the first example of establishing a successful, reproducible solvent-based synthesis route for a pure, crystalline, stable transition metal borohydride. The new polymorph, γ-Mn(BH₄)₂, is shown to be the manganese counterpart of the zeolite-like compound, γ-Mg(BH₄)₂ (cubic, a = 16.209(1) Å, space group Ida). It is verified that large pores (diameter > 6.0 Å) exist in this structure. The solvate, Mn(BH₄)₂·1/2S(CH₃)₂, is subsequently shown to be the analogue of Mg(BH₄)₂·1/2S(CH₃)₂. As the structural analogies between Mg(BH₄)₂ and Mn(BH₄)₂ became evident a new polymorph of Mg(BH₄)₂ was identified and termed ζ-Mg(BH₄)₂. ζ-Mg(BH₄)₂ is the structural counterpart of α-Mn(BH₄)₂. All synthesis products are characterized employing synchrotron radiation-powder X-ray diffraction, infrared spectroscopy and thermogravimetric analysis in combination with mass spectroscopy. Thermal analysis reveals the decomposition of Mn(BH₄)₂ to occur at 160 °C, accompanied by a mass loss of 14.8 wt%. A small quantity of the desorbed gaseous species is identified as diborane (ρ_m(Mn(BH₄)₂) = 9.5 wt% H₂), while the remaining majority is found to be hydrogen.