Iron-Catalyzed Activation of Carbon–Halogen Bonds

We have studied the cross-coupling reaction of C(spn)–X bonds (n = 1–3; X = F, Cl, Br, I) mediated by the model iron-d8 catalyst Fe(CO)4 with the archetypal model substrates H3C–CH2–X, H2C═CH–X, and HC≡C–X, utilizing relativistic density functional theory at ZORA-OPBE/TZ2P. The barrier of the oxidative-addition step decreases as the C(spn)–X bond varies from X = F to Cl to Br to I and from C(sp3) to C(sp2) to C(sp). Activation strain and energy decomposition analyses uncover that the lowering of the reaction barrier from X = F to I is caused by (i) a weaker C(spn)–X bond that needs to be broken, (ii) enhanced HOMO–LUMO interactions, and (iii) a stronger electrostatic attraction between the catalyst and the substrate due to the more diffuse electron density and higher nuclear charge of the X atom when varying from X = F to I.