Abstract

Simulated annealing and potential function smoothing are two widely used approaches for global energy optimization of molecular systems. Potential smoothing as implemented in the diffusion equation method has been applied to study partitioning of the potential energy surface (PES) for N-Acetyl-Ala-Ala-N-Methylamide (CDAP) and the clustering of conformations on deformed surfaces. A deformable version of the united-atom OPLS force field is described, and used to locate all local minima and conformational transition states on the CDAP surface. It is shown that the smoothing process clusters conformations in a manner consistent with the inherent structure of the undeformed PES. Smoothing deforms the original surface in three ways: structural shifting of individual minima, merging of adjacent minima, and energy crossings between unrelated minima. A master equation approach and explicit molecular dynamics trajectories are used to uncover similar features in the equilibrium probability distribution of CDAP minima as a function of temperature. Qualitative and quantitative correlations between the simulated annealing and potential smoothing approaches to enhanced conformational sampling are established.

Original languageEnglish
Pages (from-to)531-552
Number of pages22
JournalJournal of Computational Chemistry
Volume21
Issue number7
DOIs
StatePublished - May 2000

Keywords

  • Clustering
  • Conformational search
  • Diffusion equation method
  • Molecular mechanics
  • Potential energy smoothing
  • Simulated annealing

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