Reformulating hyperdynamics without a transition state theory dividing surface

Abstract

Reformulating hyperdynamics without using a transition state theory (TST) dividing surface makes it possible to accelerate conventional molecular dynamics (MD) simulation using a broader range of bias potentials. A new scheme to calculate the boost factor is also introduced that makes the hyperdynamics method more accurate and efficient. Novel bias potentials using the hyper-distance and the potential energy slope and curvature along the direction vector from a minimum to a current position can significantly reduce the computational overhead required. Results simulating an atomic force microscope (AFM) system validate the new methodology.