Switchable Surface Properties through the Electrochemical or Biocatalytic Generation of Ag⁰ Nanoclusters on Monolayer-Functionalized Electrodes

The electroswitchable and the biocatalytic/electrochemical switchable interfacial properties of a Ag⁺-biphenyldithiol (BPDT) monolayer associated with a Au surface are described. Upon the application of a potential corresponding to -0.2 V the Ag⁺-BPDT is reduced to the Ag⁰-BPDT interface, and silver nanoclusters are generated on the interface. The application of a potential that corresponds to 0.2 V reoxidizes the monolayer to the Ag⁺-BPDT monolayer. The reversible electrochemical transformation of the Ag⁺-BPDT monolayer and of the Ag⁰-BPDT surface was followed by electrochemical means and surface plasmon resonance spectroscopy (SPR). The SPR experiments enabled us to follow the kinetics of nanoclustering of Ag⁰ on the surface. The hydrophobic/hydrophilic properties of the surface are controlled by the electrochemically induced transformation of the interface between the Ag⁺-BPDT and Ag⁰-BPDT states. The Ag⁰-BPDT monolayer reveals enhanced hydrophilicity. The hydrophobic/hydrophilic properties of the interface were probed by contact angle measurements and force interactions with a hydrophobicallyfunctionalized AFM tip. The Ag⁰-BPDT interface was also biocatalytically generated using alkaline phosphatase, AlkPh, and p-aminophenyl phosphate as substrate. The biocatalytically generated paminophenol reduces Ag⁺ ions associated with the surface to Ag⁰ nanoclusters. This enables the cyclic biocatalytic/electrochemical control of the surface properties of the modified electrode.