posted on 2021-01-06, 19:09authored byRobin Tyburski, Tianfei Liu, Starla D. Glover, Leif Hammarström
Proton-coupled
electron transfer (PCET) reactions are fundamental
to energy transformation reactions in natural and artificial systems
and are increasingly recognized in areas such as catalysis and synthetic
chemistry. The interdependence of proton and electron transfer brings
a mechanistic richness of reactivity, including various sequential
and concerted mechanisms. Delineating between different PCET mechanisms
and understanding why a particular mechanism dominates are crucial
for the design and optimization of reactions that use PCET. This Perspective
provides practical guidelines for how to discern between sequential
and concerted mechanisms based on interpretations of thermodynamic
data with temperature-, pressure-, and isotope-dependent kinetics.
We present new PCET-zone diagrams that show how a mechanism can switch
or even be eliminated by varying the thermodynamic (ΔGPT° and ΔGET°) and coupling strengths for a PCET system.
We discuss the appropriateness of asynchronous concerted PCET to rationalize
observations in organic reactions, and the distinction between hydrogen
atom transfer and other concerted PCET reactions. Contemporary issues
and future prospects in PCET research are discussed.