Abstract
Elucidation of mesoscopic structures of molecular systems is of considerable scientific and technological interest for the development and optimization of advanced materials. Molecular dynamics simulations are a promising means of revealing macroscopic physical properties of materials from a microscopic viewpoint, but analysis of the resulting complex mesoscopic structures from microscopic information is a non-trivial and challenging task. In this study, a Machine Learning-aided Local Structure Analyzer (ML-LSA) is developed to classify the complex local mesoscopic structures of molecules that have not only simple atomistic group units but also rigid anisotropic functional groups such as mesogens. The proposed ML-LSA is applied to classifying the local structures of liquid crystal polymer (LCP) systems, which are of considerable scientific and technological interest because of their potential for sensors and soft actuators. A machine learning (ML) model is constructed from small, and thus computationally less costly, monodomain LCP trajectories. The ML model can distinguish nematic- and smectic-like monodomain structures with high accuracy. The ML-LSA is applied to large, complex quenched LCP structures, and the complex local structures are successfully classified as either nematic- or smectic-like. Furthermore, the results of the ML-LSA suggest the best order parameter for distinguishing the two mesogenic structures. Our ML model enables automatic and systematic analysis of the mesogenic structures without prior knowledge, and thus can overcome the difficulty of manually determining the specific order parameter required for the classification of complex structures.
Highlights
Elucidation of mesoscopic structures of molecular systems is of considerable scientific and technological interest for the development and optimization of advanced materials
We have developed a Machine Learning-aided Local Structure Analyzer (ML-LSA) to classify the structures of liquid crystal polymer (LCP) containing rigid ellipsoidal particles
For monodomain LCP trajectories, machine learning (ML)-LSA can distinguish between two structures using only the coordinates of the 1–4 nearest particles, which contain very little information about local structures
Summary
Elucidation of mesoscopic structures of molecular systems is of considerable scientific and technological interest for the development and optimization of advanced materials. A Machine Learning-aided Local Structure Analyzer (ML-LSA) is developed to classify the complex local mesoscopic structures of molecules that have simple atomistic group units and rigid anisotropic functional groups such as mesogens. Our ML model enables automatic and systematic analysis of the mesogenic structures without prior knowledge, and can overcome the difficulty of manually determining the specific order parameter required for the classification of complex structures. For mass point or spherical particle systems, several analysis methods that focus on the arrangement of particles have been widely accepted[1] These methods are based on particle coordinates and can classify many types of molecular forms, such as liquid, solid, body-centered cubic, face-centered cubic, hexagonal close-packed, and vacancy structures. The proposed ML-LSA was applied to classifying the local structures of liquid crystal polymer (LCP) systems
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