Combined Crossed Molecular Beams and Ab Initio Study of the Bimolecular Reaction of Ground State Atomic Silicon (Si; 3 P) with Germane (GeH4 ; X1 A1 )

Gas Phase Preparation of the Elusive Monobridged Ge(µ -H)GeH Molecule via Non-Adiabatic Reaction Dynamics

The hitherto elusive monobridged Ge( µ -H)GeH (X 1 A') molecule was prepared in gas phase through bimolecular reaction of atomic germanium (Ge) with germane (GeH 4 ). Merged with electronic structure calculations, this reaction was revealed to commence on the triplet surface with the formation of a van der Waals complex, followed by insertion of germanium into a germanium-hydrogen bond via a submerged barrier forming the triplet digermanylidene intermediate (HGeGeH 3 ); the latter underwent intersystem crossing from the triplet to singlet surface. On the singlet surface, HGeGeH 3 predominantly isomerized via two successive hydrogen shifts prior to unimolecular decomposition to Ge( µ -H)GeH isomer, which is in equilibrium with the vinylidene-type (H 2 GeGe) and di-bridged (Ge( µ -H 2 )Ge) isomers. This reaction leads to the formation of the cyclic dinuclear germanium molecules, which do not exist on the isovalent C 2 H 2 surface, deepening our understanding of the role of nonadiabatic reaction dynamics in preparing non-classical, hydrogen-bridged isomers carrying main group XIV elements.