Abstract
This paper gives a systematic method for constructing an N-body potential, approximating the true potential, that accurately captures meso-scale behavior of the chemical or biological system using pairwise potentials coming from experimental data or ab initio methods. The meso-scale behavior is translated into logic rules for the dynamics. Each pairwise potential has an associated logic function that is constructed using the logic rules, a class of elementary logic functions, and AND, OR, and NOT gates. The effect of each logic function is to turn its associated potential on and off. The N-body potential is constructed as linear combination of the pairwise potentials, where the “coefficients” of the potentials are smoothed versions of the associated logic functions. These potentials allow a potentially low-dimensional description of complex processes while still accurately capturing the relevant physics at the meso-scale. We present the proposed formalism to construct coarse-grained potential models for three examples: an inhibitor molecular system, bond breaking in chemical reactions, and DNA transcription from biology. The method can potentially be used in reverse for design of molecular processes by specifying properties of molecules that can carry them out.
Highlights
It is profitable to restrict one’s efforts to considering approximate potentials that respect known behavior
The logic functions are turned into smooth encoding functions via a replacement procedure which in turn are used to modify the pairwise potentials
In the Methodology section, we define the major components of the framework — logic functions, permissible logical operations, and the translation to the associated encoding functions — and specify how they combine with the pairwise potentials to define the approximate potential
Summary
It is profitable to restrict one’s efforts to considering approximate potentials that respect known behavior Such coarse-level descriptions may be determined from experimental observation and may correspond to trajectories in some transformed (reaction) coordinate system. This article introduces a method of encoding coarse-level dynamical behavior into logic functions that are used to “stitch” together pairwise interaction potentials into an N-body potential. The method generates a potential that respects what is currently known about the system; it is not claimed that this method results in the unique potential governing the real system The method does this by leveraging the existing experimental data and the coarse-level behavior that can be derived from it.
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