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The First Halide-Free Bimetallic Aluminum Borohydride: Synthesis, Structure, Stability, and Decomposition Pathway
Interaction of solid KBH<sub>4</sub> with liquid AlĀ(BH<sub>4</sub>)<sub>3</sub> at room temperature yields
a solid bimetallic borohydride
KAlĀ(BH<sub>4</sub>)<sub>4</sub>. According to the synchrotron X-ray
powder diffraction, its crystal structure (space group <i>Fddd,
a</i> = 9.7405(3), <i>b</i> = 12.4500(4), and <i>c</i> = 14.6975(4) Ć
) contains a substantially distorted
tetrahedral [AlĀ(BH<sub>4</sub>)<sub>4</sub>]<sup>ā</sup> anion,
where the borohydride groups are coordinated to aluminum atoms via
edges. The Ī·<sup>2</sup>-coordination of BH<sub>4</sub><sup>ā</sup> is confirmed by the infrared and Raman spectroscopies.
The title compound is the first aluminum-based borohydride complex
not stabilized by halide anions or by bulky organic cations. It is
not isostructural to bimetallic chlorides, where more regular tetrahedral
AlCl<sub>4</sub><sup>ā</sup> anions are present. Instead, it
is isomorphic to the LT phase of TbAsO<sub>4</sub> and can be also
viewed as consisting of two interpenetrated <i>dia</i>-type
nets where BH<sub>4</sub> ligand is bridging Al and K cations. Variable
temperature X-ray powder diffraction, TGA, DSC, and TGA-MS data reveal
a single step of decomposition at 160 Ā°C, with an evolution of
hydrogen and some amount of diborane. Aluminum borohydride is not
released in significant amounts; however, some crystalline KBH<sub>4</sub> forms upon decomposition. The higher decomposition temperature
than in chloride-substituted LiāAl (70 Ā°C) and NaāAl
(90 Ā°C) borohydrides suggests that the larger alkali metal cations
(weaker Pearson acids) stabilize the weak Pearson base, [AlĀ(BH<sub>4</sub>)<sub>4</sub>]<sup>ā</sup>