Parameter optimization in differential geometry based solvation models

Differential geometry (DG) based solvation models are a new class of variational implicit solvent approaches that are able to avoid unphysical solvent-solute boundary definitions and associated geometric singularities, and dynamically couple polar and non-polar interactions in a self-consistent fram...

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Bibliographic Details
Published in:The Journal of chemical physics 2015-10, Vol.143 (13), p.134119-134119
Main Authors: Wang, Bao, Wei, G W
Format: Article
Language:English
Subjects:
Algorithms
Computational geometry
Convexity
Coupling (molecular)
Differential geometry
Free energy
Machine learning
Mathematical models
Models, Chemical
Nonlinear equations
Optimization
Parameterization
Parameters
Quantum Theory
Singularities
Solvation
Solvents
Solvents - chemistry
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Summary:Differential geometry (DG) based solvation models are a new class of variational implicit solvent approaches that are able to avoid unphysical solvent-solute boundary definitions and associated geometric singularities, and dynamically couple polar and non-polar interactions in a self-consistent framework. Our earlier study indicates that DG based non-polar solvation model outperforms other methods in non-polar solvation energy predictions. However, the DG based full solvation model has not shown its superiority in solvation analysis, due to its difficulty in parametrization, which must ensure the stability of the solution of strongly coupled nonlinear Laplace-Beltrami and Poisson-Boltzmann equations. In this work, we introduce new parameter learning algorithms based on perturbation and convex optimization theories to stabilize the numerical solution and thus achieve an optimal parametrization of the DG based solvation models. An interesting feature of the present DG based solvation model is that it provides accurate solvation free energy predictions for both polar and non-polar molecules in a unified formulation. Extensive numerical experiment demonstrates that the present DG based solvation model delivers some of the most accurate predictions of the solvation free energies for a large number of molecules.
ISSN:0021-9606
1089-7690
DOI:10.1063/1.4932342