Acoustic Modulation of Ion-Solvent Interactions: Microscopic Insights into Acoustoelectric Effect Modelling

The acoustoelectric (AE) effect, in which acoustic waves modulate the electrical properties of a conductive medium, holds significant potential for biomedical imaging. While classic models describe the phenomenon through conductivity modulation, a detailed understanding of its microscopic origins, particularly the role of ion behaviours, remains lacking. This study introduces a novel electrokinetic perspective by investigating how ultrasound modulates ion-solvent interactions, thereby bridging macroscopic AE signals with underlying ion dynamics. Through finite element simulations of a dilute NaCl solution, we demonstrate that acoustic pressure waves induce local variations in ion mobility and diffusion by altering ion hydration shells and solvent viscosity. These changes disrupt the balance among Coulombic, diffusive, and frictional forces on individual ions, leading to the local conductivity modulation. Furthermore, simulations reveal that acoustic perturbation of the electrode-electrolyte interface (EEI) significantly enhances AE signal generation, highlighting the EEIs critical role in AE-related applications. By linking acoustic modulation to fundamental ion-solvent interactions, this work not only provides a foundation for more accurate, microscopically grounded models of the AE effect but also connects AE effect modelling to the active research of solvation dynamics in physical chemistry.