Abstract
AbstractNoncovalent chemical interactions, including electrostatic interactions, hydrogen bonding, and hydrophobic interactions, constitute crucial driving forces in the bottom‐up assembly of multifunctional molecular complexes and nanomaterials. Electrostatic interactions in chemical environments are generally considered as non‐specific interactions, which pose notable challenges for the control and direct measurement of electrostatic forces at the single‐molecule level. Here, we report a model system consisting of cytochrome c and molecules containing carboxyl groups, and use electrochemical AFM force spectroscopy to navigate the electrostatic forces of the system under various chemical conditions. The effects of solution pH, ion strength, and redox states of cytochrome c on electrostatic interactions as well as control over these parameters are systematically studied. This work provides a useful approach for investigating intermolecular electrostatic interactions at the single‐molecule level.
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