Impact of Surface Chemistry on Emulsion–Electrode Interactions and Electron-Transfer Kinetics in the Single-Entity Electrochemistry

Abstract: Single-entity electrochemistry (SEE) provides powerful means to track a single particle, single cell, and even single molecule from the nano to microscale. The electrode serves as not only the detector of collision but also the surface supplier in SEE, and the fundamental understanding of the electrode surface chemistry on the dynamic particle−electrode interactions and electrochemical responses of a single particle still remains unexplored, particularly for soft particles. Herein, dynamic interactions of micr… Show more

“…This approach allows for atomic restructuring and dynamic changes to chemical reactivity to be monitored as the applied electrochemical potential is cycled. In a different approach, Du et al formed Nile Red-doped emulsions of nitrobenzene in water, allowing SE collisions to be imaged using fluorescence microscopy . Electrochemical data of the collision of the emulsions with either gold or carbon ultramicroelectrodes showed a difference in the number of collisions and electron-transfer kinetics based on the electrode material.…”

“…In a different approach, Du et al formed Nile Red-doped emulsions of nitrobenzene in water, allowing SE collisions to be imaged using fluorescence microscopy. 231 Electrochemical data of the collision of the emulsions with either gold or carbon ultramicroelectrodes showed a difference in the number of collisions and electron-transfer kinetics based on the electrode material. Fluorescence microscopy data revealed that the slower electron-transfer kinetics and reduced number of collisions on the carbon ultramicroelectrode surface were due to the adsorption and coalescence of the emulsions, which formed a thin organic layer that blocked the surface of the electrode, slowing electron-transfer rates in subsequent collision events.…”

Recent Developments in Single-Entity Electrochemistry

“…This approach allows for atomic restructuring and dynamic changes to chemical reactivity to be monitored as the applied electrochemical potential is cycled. In a different approach, Du et al formed Nile Red-doped emulsions of nitrobenzene in water, allowing SE collisions to be imaged using fluorescence microscopy . Electrochemical data of the collision of the emulsions with either gold or carbon ultramicroelectrodes showed a difference in the number of collisions and electron-transfer kinetics based on the electrode material.…”

“…In a different approach, Du et al formed Nile Red-doped emulsions of nitrobenzene in water, allowing SE collisions to be imaged using fluorescence microscopy. 231 Electrochemical data of the collision of the emulsions with either gold or carbon ultramicroelectrodes showed a difference in the number of collisions and electron-transfer kinetics based on the electrode material. Fluorescence microscopy data revealed that the slower electron-transfer kinetics and reduced number of collisions on the carbon ultramicroelectrode surface were due to the adsorption and coalescence of the emulsions, which formed a thin organic layer that blocked the surface of the electrode, slowing electron-transfer rates in subsequent collision events.…”

Recent Developments in Single-Entity Electrochemistry

Collision electrochemistry: A simple methodology for investigating complex processes