(iii) electromagnetic applications (Cu, Nb, Ta, W, Re, etc.). Over the past several decades, their superb properties as chemically useful substances, especially as catalysts for chemical reactions, have been increasingly recognized. “Why are they so useful as catalysts?”
In most cases, their superb catalytic properties may be attributed to one or both of the following two: (1) ability to provide simultaneously both filled nonbonding valence-shell orbitals (one or more) and empty valence-shell orbitals (one or more) within thermally stable species and (2) ability to undergo simultaneously both reduction and oxidation under one set of reaction conditions in one reaction vessel.
A combination of these two properties can be exploited in devising a wide variety of useful catalytic reactions for formation and cleavage of C–C, C–H, C–O and other bonds.
For critically important C–C bond formation, a) reductive elimination, b) carbometalation, and c) migratory insertion may be exploited. As representative examples of reductive elimination and carbometalation, the Pd-catalyzed cross-coupling proceeding via reductive elimination and Zr-catalyzed asymmetric carboalumination of alkenes (ZACA) proceeding via carbometalation will be discussed.
Many more novel catalytic one- and two-electron processes via organotransition metals will be discovered and developed.