Computational Screening of MOF Supported Transition Metal Catalysts for Activity and Selectivity in Ethylene Dimerization
Ye, J.; Gagliardi, L.; Cramer, C. J.; Truhlar, D. G.
J. Catal.
2018, 360, 160
(doi:10.1016/j.jcat.2017.12.007).
Deposition of small metal-oxide clusters on the Zr-based nodes of a metal-organic framework has been demonstrated to provide access to a variety of single-site catalysts. Well-defined catalytic active sites are amenable to detailed computational studies of potential catalytic pathways, and they invite screening a wide range of metals to assess their expected activity. Here we report the application of density functional theory to a variety of transition metals (in particular TiIV, VII, VIV, CrII, CrIII, MnII, MnIV, FeII, FeIII, NiII, CoII, CoIII, CuII, CuIII, PdII, MoII, and WII) supported on NU-1000 inorganometallic nodes to evaluate their activity for ethylene dimerization. We found that the rate-determining step varies between different catalysts, which illustrates the importance of considering more than a single step when comparing catalytic cycles across a variety of metals. Our calculations are consistent with the known good activity of supported NiII for ethylene dimerization, and they predict that CrII and PdII are also potentially useful catalysts for this process. We also screen modifications to the organic linker of NiII-NU-1000 by considering the addition of Me, iPr, tBu, and CF3 groups to study the influence of sterically demanding and, in the case of CF3, electron-withdrawing, substituents on the activity for ethylene dimerization; we predict no improvements in activity or selectivity (for 1-butene) with such substitutions.