Dual Control of Molecular Conductance through pH and Potential in Single-Molecule Devices
Author(s):
Richard J. Brooke, Doug S. Szumski, Andrea Vezzoli, Simon J. Higgins, Richard J. Nichols, Walther Schwarzacher
Journal:
Nano Letters
Year:
2018
Volume:
18
Pages
1317-1322
DOI:
10.1021/acs.nanolett.7b04995
Abstract:
One of the principal aims of single-molecule electronics is to create practical devices out of individual molecules. Such devices are expected to play a particularly important role as novel sensors thanks to their response to wide ranging external stimuli. Here we show that the conductance of a molecular junction can depend on two independent stimuli simultaneously. Using a scanning tunnelling microscope break-junction technique (STM-BJ), we found that the conductance of 4,4′-vinylenedipyridine (44VDP) molecular junctions with Ni contacts depends on both the electrochemically applied gate voltage and the pH of the environment. Hence, not only can the Ni|44VDP|Ni junction function as a pH-sensitive switch, but the value of the pH at which switching takes place can be tuned electrically. Furthermore, through the simultaneous control of pH and potential the STM-BJ technique delivers unique insight into the acid–base reaction, including the observation of discrete proton transfers to and from a single molecule.