Machine Learning-Assisted Profiling of Ladder Polymer Structure using Scattering
Abstract
Ladder polymers, known for their rigid, ladder-like structures, exhibit exceptional thermal stability and mechanical strength, positioning them as candidates for advanced applications. However, accurately determining their structure from solution scattering remains a challenge. Their chain conformation is largely governed by the intrinsic orientational properties of the monomers and their relative orientations, leading to a bimodal distribution of bending angles, unlike conventional polymer chains whose bending angles follow a unimodal Gaussian distribution. Meanwhile, traditional scattering models for polymer chains do not account for these unique structural features. This work introduces a novel approach that integrates machine learning with Monte Carlo simulations to address this challenge. We first develop a Monte Carlo simulation for sampling the configuration space of ladder polymers, where each monomer is modeled as a biaxial segment. Then, we establish a machine learning-assisted scattering analysis framework based on Gaussian Process Regression. Finally, we conduct small-angle neutron scattering experiments on a ladder polymer solution to apply our approach. Our method uncovers structural details of ladder polymers that conventional methods fail to capture.
Cite
@article{arxiv.2411.00134,
title = {Machine Learning-Assisted Profiling of Ladder Polymer Structure using Scattering},
author = {Lijie Ding and Chi-Huan Tung and Zhiqiang Cao and Zekun Ye and Xiaodan Gu and Yan Xia and Wei-Ren Chen and Changwoo Do},
journal= {arXiv preprint arXiv:2411.00134},
year = {2025}
}
Comments
8 pages, 9 figures,