Transition‐State Energy and Position along the Reaction Coordinate in an Extended Activation Strain Model

We investigate palladium‐induced activation of the CH, CC, CF, and CCl bonds in methane, ethane, cyclopropane, fluoromethane, and chloromethane, using relativistic density functional theory (DFT) at ZORA‐BLYP/TZ2P. Our purpose is to arrive at a qualitative understanding, based on accurate calculations, of the trends in activation barriers and transition state (TS) geometries (e.g. early or late along the reaction coordinate) in terms of the reactants’ properties. To this end, we extend the activation strain model (in which the activation energy ΔE ≠ is decomposed into the activation strain ΔE ≠ strain of the reactants and the stabilizing TS interaction ΔE ≠ int between the reactants) from a single‐point analysis of the TS to an analysis along the reaction coordinate ζ , that is, ΔE(ζ)=ΔE strain (ζ)+ΔE int (ζ). This extension enables us to understand qualitatively, trends in the position of the TS along ζ and, therefore, the values of the activation strain ΔE ≠ strain =ΔE strain (ζ TS ) and TS interaction ΔE ≠ int =ΔE int ( ζ TS ) and trends therein. An interesting insight that emerges is that the much higher barrier of metal‐mediated CC versus CH activation originates from steric shielding of the CC bond in ethane by CH bonds. Thus, before a favorable stabilizing interaction with the CC bond can occur, the CH bonds must be bent away, which causes the metal–substrate interaction ΔE int (ζ) in CC activation to lag behind. Such steric shielding is not present in the metal‐mediated activation of the CH bond, which is always accessible from the hydrogen side. Other phenomena that are addressed are anion assistance, competition between direct oxidative insertion (OxIn) versus the alternative S N 2 pathway, and the effect of ring strain.