Identifying local structures in dipolar colloid-polymer mixtures using machine learning

Sheigani, Vahid (2023) Identifying local structures in dipolar colloid-polymer mixtures using machine learning. Memorial University of Newfoundland. (Unpublished)

[img] [English] PDF (Undergraduate Honours Thesis) - Accepted Version
Available under License - The author retains copyright ownership and moral rights in this thesis. Neither the thesis nor substantial extracts from it may be printed or otherwise reproduced without the author's permission.

Download (17MB)

Abstract

A colloid-polymer mixture with an applied electric field is subject to two categories of forces, the induced dipole-dipole interactions and depletion forces due to the polymer. The combination of these forces with different polymer concentrations and external electric fields results in the formation of various structures with different local orders. To study these structures in more detail, the colloid-polymer system can be replicated computationally using the molecular dynamics method which enables us to calculate particle features such as bond order parameters computationally and further investigate these features using advanced methods such as machine learning. In this thesis, we apply a multi-step machine learning algorithm to dipolar-depletion systems and identify the local structure of atoms in the simulation box using the algorithm. The machine learning algorithm is a combination of multiple cutting-edge machine learning techniques including autoencoders, Gaussian mixture models, and a cluster merging technique. These algorithms are combined to create a multi-step process that can identify different structures of matter in any molecular dynamics simulation output. This algorithm utilizes unsupervised machine learning which does not require labeled data and is applicable to known and unknown local structures. The machine learning model can identify different local structures in colloid-polymer systems and the identified clusters of atoms in the systems is in complete agreement with our understanding of the systems.

Item Type: Other
URI: http://research.library.mun.ca/id/eprint/16299
Item ID: 16299
Additional Information: Includes bibliographical references (pages 63-64)
Department(s): Science, Faculty of > Physics and Physical Oceanography
Date: October 2023
Date Type: Submission
Library of Congress Subject Heading: Colloids; Polymers; Electric fields; Machine learning; Dipole moments

Actions (login required)

View Item View Item

Downloads

Downloads per month over the past year

View more statistics