posted on 2021-12-15, 07:43authored byTimothy
R. Wilson, Anastassia N. Alexandrova, M. E. Eberhart
A novel form of charge density analysis,
that of isosurface curvature
redistribution, is formulated and applied to the toy problem of carbonyl
oxygen activation in formaldehyde. The isosurface representation of
the electron charge density allows us to incorporate the rigorous
geometric constraints of closed surfaces toward the analysis and chemical
interpretation of the charge density response to perturbations. Visual
inspection of 2D isosurface motion resulting from applied external
electric fields reveals how the isosurface curvature flows within
and between atoms and that a molecule can be uniquely and completely
partitioned into chemically significant regions of positive and negative
curvatures. These concepts reveal that carbonyl oxygen activation
proceeds primarily through curvature and charge redistribution within
rather than between Bader atoms. Using gradient bundle analysisthe
partitioning of formaldehyde into infinitesimal volume elements bounded
by QTAIM zero-flux surfacesthe observations from visual isosurface
inspection are verified. The results of the formaldehyde carbonyl
analysis are then shown to be transferable to the substrate carbonyl
in the ketosteroid isomerase enzyme, laying the groundwork for extending
this approach to the problems of enzymatic catalysis.