Perovskite alkali metal samarium borohydrides: crystal structures and thermal decomposition.

Author(s) Møller, K.T.; Jørgensen, M.; Fogh, A.S.; Jensen, T.R.
Journal Dalton Trans
Date Published 2017 Sep 12
Abstract

A new synthesis method of samarium borohydride, Sm(BH4)2, using tetrahydrofuran borane, THF-BH3, and samarium hydride, SmH2, has been demonstrated and verified. The synthesised Sm(BH4)2 was mechanochemically treated with MBH4, M = K, Rb, Cs. Initially, the formation of KSm(BH4)3 is observed while subsequent heat treatment is necessary to form MSm(BH4)3, M = Rb, Cs. The new compounds crystallise in orthorhombic unit cells adopting perovskite-type 3D frameworks containing distorted [Sm(BH4)6] octahedra. In situ X-ray diffraction studies reveal two second-order polymorphic transitions of α-CsSm(BH4)3via a tetragonal intermediate, α'-CsSm(BH4)3, into a cubic high-temperature polymorph, β-CsSm(BH4)3, resembling an ideal perovskite structure. The new compounds, MSm(BH4)3, are thermally stable up to T ∼ 280 °C after which they decompose into mainly MBH4, SmH2 and possibly SmB6 and SmB12H12. Finally, after three cycles of hydrogen release and uptake, the storage capacity was 1.0 wt% for KSm(BH4)3 and 0.84 wt% for RbSm(BH4)3 and CsSm(BH4)3.

DOI 10.1039/c7dt02405c
ISSN 1477-9234
Citation Møller KT, Jørgensen M, Fogh AS, Jensen TR. Perovskite alkali metal samarium borohydrides: crystal structures and thermal decomposition. Dalton Trans. 2017;46(35):11905-11912.

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