Reference electrode (RE) plays the core role in accurate
potential
control in electrochemistry. However, nanoresolved electrochemical
characterization techniques still suffer from unstable potential control
of pseudo-REs, because the commercial RE is too large to be used in
the tiny electrochemical cell, and thus only pseudo-RE can be used.
Therefore, microsized RE with a stable potential is urgently required
to push the nanoresolved electrochemical measurements to a new level
of accuracy and precision, but it is quite challenging to reproducibly
fabricate such a micro RE until now. Here, we revisited the working
mechanism of the metal-junction RE and clearly revealed the role of
the ionic path between the metal wire and the borosilicate glass capillary
to maintain a stable potential of RE. Based on this understanding,
we developed a method to fabricate micro ultrastable-RE, where a reproducible
ultrathin ionic path can form by dissolving a sandwiched sacrificial
layer between the Pt wire and the capillary for the ion transfer.
The potential of this new micro RE was almost the same as that of
the commercial Ag/AgCl electrode, while the size is much smaller.
Different from commercial REs that must be stored in the inner electrolyte,
the new RE could be directly stored in air for more than one year
without potential drift. Eventually, we successfully applied the micro
RE in the electrochemical tip-enhanced Raman spectroscopy (EC-TERS)
measurement to precisely control the potential of the working electrode,
which makes it possible to compare the results from different laboratories
and techniques to better understand the electrochemical interface
at the nanoscale.