posted on 2017-12-08, 00:00authored byTerry Z. H. Gani, Heather J. Kulik
Computational high-throughput screening
is an essential tool for catalyst design, limited primarily by the
efficiency with which accurate predictions can be made. In bulk heterogeneous
catalysis, linear free energy relationships (LFERs) have been extensively
developed to relate elementary step activation energies, and thus
overall catalytic activity, back to the adsorption energies of key
intermediates, dramatically reducing the computational cost of screening.
The applicability of these LFERs to single-site catalysts remains
unclear, owing to the directional, covalent metal–ligand bonds
and the broader chemical space of accessible ligand scaffolds. Through
a computational screen of nearly 500 model Fe(II) complexes for CH4 hydroxylation, we observe that (1) tuning ligand field strength
yields LFERs by comparably shifting energetics of the metal 3d levels
that govern the stability of different intermediates and (2) distortion
of the metal coordination geometry breaks these LFERs by increasing
the splitting between the dxz/dyz and dz2 metal
states that govern reactivity. Thus, in single-site catalysts, low
Brønsted–Evans–Polanyi slopes for oxo formation,
which would limit peak turnover frequency achievable through ligand
field tuning alone, can be overcome through structural distortions
achievable in experimentally characterized compounds. Observations
from this screen also motivate the placement of strong HB donors in
targeted positions as a scaffold-agnostic strategy for further activity
improvement. More generally, our findings motivate broader variation
of coordination geometries in reactivity studies with single-site
catalysts.