posted on 2024-11-30, 03:31authored byMahdi Tavakol, Alexander Newbold, Kislon Voïtchovsky
The organization
and dynamics of ions and water molecules
at electrified
solid–liquid interfaces are generally well understood under
static fields, especially for macroscopic electrochemical systems.
In contrast, studies involving alternating (AC) fields tend to be
more challenging. In nanoscale systems, added complexity can arise
from interfacial interactions and the need to consider ions and molecules
explicitly. Here we use molecular dynamics (MD) simulations to investigate
the behavior of NaCl aqueous solutions at different concentrations
confined in nanogaps under AC fields ranging from 10 MHz to 10 GHz.
We explore the impact of the gap size (2–60 nm) and of the
solid material composing the electrode (silica, charged silica, or
gold). Analysis of the transient and stable responses of the system
shows that the total transverse dipole Mz,total formed by the water molecules and the ions
across the gap is always able to counter the applied field regardless
of AC frequency, NaCl concentration, or electrode material. As expected,
the ions lag at higher frequencies, leading to a capacitive behavior.
This effect is fully compensated by water dipoles that lead the field,
reaching a maximum lead at a specific frequency which depends on salt
concentration and gap size. Changing the gap size affects the magnitude
of Mz,total. Finally,
the electrode material is shown to affect the electrolyte behavior
in the gap region. We anticipate these results to be useful for nanoscale
dielectric spectroscopy, including scanning probes.