2023 article
Electrode-Potential-Driven Dissociation of N-Heterocycle/BF3 Adducts: A Possible Manifestation of the Electro-Inductive Effect
Hossain, M. S., Romo, A. I. B., Putnam, S. T., Dawlaty, J., Augustyn, V., & Rodriguez-Lopez, J. (2023, May 4). ANGEWANDTE CHEMIE-INTERNATIONAL EDITION.
author keywords: Adduct; Electro-Inductive Effect; Electrostatics; Fluorescence; Scanning Electrochemical Microscopy
open access via onlinelibrary.wiley.com (publisher PDF)
Source: Web Of Science
Added: May 30, 2023
AbstractRecently, non‐Faradaic effects were used to modify the electronic structure and reactivity of electrode‐bound species. We hypothesize that these electrostatic perturbations could influence the chemical reactivity of electrolyte species near an electrode in the absence of Faradaic electron transfer. A prime example of non‐Faradaic effects is acid‐base dissociation near an interface. Here, we probed the near‐electrode dissociation of N‐heterocycle‐BF3 Lewis adducts upon electrode polarization, well outside of the redox potential window of the adducts. Using scanning electrochemical microscopy and confocal fluorescence spectroscopy, we detected a potential‐dependent depletion of the adduct near the electrode. We propose an electro‐inductive effect where a more positive potential leads to electron withdrawal on the N‐heterocycle. This study takes a step forward in the use of electrostatics at electrochemical interfaces for field‐driven electrocatalytic and electro‐synthetic processes.