Proton-coupled electron
transfer (PCET) reactions at various interfaces
(liquid/membrane, solid/electrolyte, liquid/liquid) lie at the heart
of many processes in biology and chemistry. Mechanistic study can
provide profound understanding of PCET and rational design of new
systems. However, most mechanisms of PCET reactions at a liquid/liquid
interface have been proposed based on electrochemical and spectroscopic
data, which lack direct evidence for possible intermediates. Moreover,
a liquid/liquid interface as one type of soft interface is dynamic,
making the investigation of interfacial reactions very challenging.
Herein a novel electrochemistry method coupled to mass spectrometry
(EC-MS) was introduced for in situ study of the oxygen reduction reaction
(ORR) by ferrocene (Fc) under catalysis from cobalt tetraphenylporphine
(CoTPP) at liquid/liquid interfaces. The key units are two types of
gel hybrid ultramicroelectrodes (agar-gel/organic hybrid ultramicroelectrodes
and water/PVC-gel hybrid ultramicroelectrodes), which were made based
on dual micro- or nanopipettes. A solidified liquid/liquid interface
can be formed at the tip of these pipettes, and it serves as both
an electrochemical cell and a nanospray emitter for mass spectrometry.
We demonstrated that the solidified L/L interfaces were very similar
to typical L/L interfaces. Key CoTPP intermediates of the ORR at the
liquid/liquid interfaces were identified for the first time, and the
four-electron oxygen reduction pathway predominated, which provides
valuable insights into the mechanism of the ORR. Theoretical simulation
has further supported the possibility of formation of intermediates.
This type of platform is promising for in situ tracking and identifying
intermediates to study complicated reactions at liquid/liquid interfaces
or other soft interfaces.