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Abstract
Spin coating is a wide-spread, quick, and inexpensive method to create nanometer-thick thin films of various polymers, such as polystyrene, on top of solid substrates. Since the film thickness determines the mechanical, optical, and degradation properties of the coated film, it is essential to develop a simple method to predict thickness based on other manipulatable factors. In this study, a three-dimensional manifold relating initial solution concentration, thin film coverage thickness, and monodisperse bulk molecular weight is developed utilizing curve-fit machine learning. The model is able to receive polystyrene bulk molecular weight and desired thin film thickness as input and output an accurate prediction of initial solution concentration required to generate a coating of a desired thickness.
Supplementary materials
Title
Supporting Information
Description
Individual function 2D graphs and equations for thickness vs. concentration and thickness vs. molecular weight, #D manifold generate by XGBoostRegressor, RMSE table of all 42 machine learning models
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Supplementary weblinks
Title
3D Manifold's Python Code and Generated Data
Description
All python code and data generated from this project is publicly available via GitHub.
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