Molybdenum Trihydride Complexes: Computational Model of Oxidatively Induced Reductive Elimination of Dihydrogen. Academic Article

abstract

• Recent experimental work shows that the 18-electron molybdenum complexes (1,2,4-C5H2tBu3)Mo(PMe3)2H3 (CptBuMoH3) and (C5HiPr4)Mo(PMe3)2H3 (CpiPrMoH3) undergo oxidatively induced reductive elimination of dihydrogen (H2), slowly forming the 15-electron monohydride species in tetrahydrofuran and acetonitrile. The 17-electron [CptBuMoH3]+ derivative was stable enough to be characterized by X-ray diffraction, while [CpiPrMoH3]+ was not. Density functional theory calculations of the H2 elimination pathways for both complexes in the gas phase and in a continuum solvent model indicate that H2 elimination from [CpiPrMoH3]+ has a lower barrier than that from [CptBuMoH3]+. Further, a specific solvent association, which is stronger for [CptBuMoH3]+ than for [CpiPrMoH3]+, contributes to the stability of the former. In agreement with the experimental observations, the calculations predict that [CptBuMoH3]+ would be in a quartet state at room temperature and a doublet state at 4.2 K, while [CpiPrMoH3]+ is in a doublet state even at room temperature.

authors

• Hall, Michael

published proceedings

• Inorg Chem

altmetric score

• 1.35

author list (cited authors)

• Szatkowski, L., & Hall, M. B.

citation count

• 2

complete list of authors

• Szatkowski, Lukasz||Hall, Michael B

publication date

• August 2017

publisher

• American Chemical Society (ACS)  Publisher

published in

• Inorganic Chemistry  Journal

PubMed Central ID

• 28795819

Digital Object Identifier (DOI)

• 10.1021/acs.inorgchem.6b02805

start page

• 9653

end page

• 9659

volume

• 56

issue

• 16

URL

• http://dx.doi.org/10.1021/acs.inorgchem.6b02805