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Abstract
The Adaptive Solvent-Scaling (AdSoS) scheme [J. Chem. Phys. 155 (2021) 094107] is an adaptive-resolution approach for performing simulations of a solute embedded in a fine- grained (FG) solvent region surrounded by a coarse-grained (CG) solvent region, with a continuous FG↔CG switching of the solvent resolution across a buffer layer. Instead of relying on a distinct CG solvent model, AdSoS is based on CG models defined by a dimensional scaling of the FG solvent by a factor s, accompanied by the s-dependent modulation of its mass and interaction parameters. The latter changes are designed to achieve an isomorphism between the dynamics of the FG and CG models, and to preserve the dispersive and dielectric solvation properties of the solvent with respect to a solute at FG resolution. As a result, the AdSoS scheme minimizes the thermodynamic mismatch between the different regions of the adaptive-resolution system. The present article generalizes the scheme initially introduced for a pure atomic liquid in slab geometry to more practically relevant situations involving: (i) a molecular dipolar solvent (e.g. water); (ii) a radial geometry (i.e. spherical rather than planar layers); and (iii) the inclusion of a solute (e.g. water molecule, dipeptide, ion or ion pair).
Supplementary materials
Title
Supporting Information
Description
Implementation details of the forces in AdSoS, the adapted SHAKE algorithm, as well as the procedures for the construction and application of the correction potentials are outlined. Plots complementing the findings in the Results section are also provided.
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