Being SERS a promising technique due to it potentially combining the well-known characterization prowess of Raman with the
high sensitivity arising from nanoparticle-associated enhancement, 1 understanding the mechanisms due to which SERS differs
from Normal Raman is key to accomplish effective applications of this technique. Following the consensus about the theoretical
background that stablishes the enhancement mechanisms in SERS, 2 and focusing on electrode potential as a variable in
Electrochemical (EC) SERS, for our work we have studied Pyridine (Py) SERS spectra modelling an EC-SERS nanostructured
surface through an Ag 6 cluster in different orientations, with an electric field parallel to the Ag 6 -Py axis reproducing electrode
potential, as depicted in Figure 1. The objective of such model is to simulate Pyridine SERS spectra and rationalizing these results
based on well-established properties, accounting for symmetry considerations, coupling terms and the influence of the solvent
on the system to carry out a straightforward understanding of SERS enhancement mechanisms. Our results are able to effectively
reproduce the main relative intensities of Pyridine SERS spectra, shedding light on the influence of the aforementioned properties
on the calculated lineshapes and intensities.