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Related Concept Videos

Classification and Mechanical Properties of Synthetic Polymers01:28

Classification and Mechanical Properties of Synthetic Polymers

Synthetic polymers are classified as elastomers, fibers, or plastics based on their crystallinity. Crystallinity, the degree of long-range order in the solid state, influences the mechanical properties (stretching or contracting) of elastomers. Elastomers are flexible polymers that can expand or contract easily upon the application of an external force. They have numerous crosslinks that pull them back into their original shape when stress is removed. Silicones, for instance, are highly elastic...
Polymer Classification: Architecture01:14

Polymer Classification: Architecture

Polymers are classified as linear or branched on the basis of their chain architecture. The polymer chains in linear polymers have a long chain-like structure with minimal to no branching at all. Even if a polymer features large substituent groups on the monomer, which appear as branches to the skeleton, it is not considered a branched polymer. A branched polymer contains secondary polymer chains that arise from the main polymer chain. The branching occurs when the polymer growth shifts from...
Polymer Classification: Stereospecificity01:26

Polymer Classification: Stereospecificity

Polymerization generates chiral centers along the entire backbone of a polymer chain. Accordingly, the stereochemistry of the substituent group has a significant effect on polymer properties. Polymers formed from monosubstituted alkene monomers feature chiral carbons at every alternate position in the polymer backbone. Relative to the predominant orientation of substituents at the adjacent chiral carbons, the polymer can exist in three different configurations: isotactic, syndiotactic, and...
Polymer Classification: Crystallinity01:21

Polymer Classification: Crystallinity

Unlike ionic or small covalent molecules, polymers do not form crystalline solids due to the diffusion limitations of their long-chain structures. However, polymers contain microscopic crystalline domains separated by amorphous domains.
Crystalline domains are the regions where polymer chains are aligned in an orderly manner and held together in proximity by intermolecular forces. For example, chains in the crystalline domains of polyethylene and nylon are bound together by van der Waals...
Types of Step-Growth Polymers: Polyesters01:20

Types of Step-Growth Polymers: Polyesters

The introduction of polyesters has brought major development to the textile industry. The wrinkle-free behavior of polyester blends has eliminated the need for starching and ironing clothes.
Polyesters are commonly prepared from terephthalic acid and ethylene glycol; the crude product is known as poly(ethylene terephthalate) or PET. However, polyesters are synthesized industrially by transesterification of dimethyl terephthalate with ethylene glycol at 150 °C. The two reactants and the polymer...
Polymers: Molecular Weight Distribution01:10

Polymers: Molecular Weight Distribution

For any given polymer, the weight average molecular weight (Mw) is higher than, if not equal to, the number average molecular weight (Mn). The only situation in which the weight average molecular weight and the number average molecular weight are equal is when a polymer consists only of chains with equal molecular weight. However, this never happens in a synthetic polymer, since it is difficult to control the polymerization process up to a molecular level with accuracy to a hundred percent.

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Related Experiment Video

Updated: May 28, 2026

Designed for Molecular Recycling: A Lignin-Derived Semi-aromatic Biobased Polymer
10:22

Designed for Molecular Recycling: A Lignin-Derived Semi-aromatic Biobased Polymer

Published on: November 30, 2020

AI-Based Polymer Classification Using Ensemble Deep Learning and Heuristic Optimization: Implications for Recycling

Mohammad Anwar Parvez1

  • 1Department of Chemical Engineering, College of Engineering, King Faisal University, P.O. Box 380, Al-Ahsa 31982, Saudi Arabia.

Polymers
|May 27, 2026
PubMed
Summary
This summary is machine-generated.

A new deep learning model, NPFRS-EDLHSA, effectively classifies polymer types using physicochemical data, advancing sustainable polymer research and recycling efforts.

Keywords:
artificial intelligencedata pre-processingensemble of deep learningfeature selectionheuristic search algorithmpolymers

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Depolymerizable Olefinic Polymers Based on Fused-Ring Cyclooctene Monomers
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Depolymerizable Olefinic Polymers Based on Fused-Ring Cyclooctene Monomers

Published on: December 16, 2022

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Last Updated: May 28, 2026

Designed for Molecular Recycling: A Lignin-Derived Semi-aromatic Biobased Polymer
10:22

Designed for Molecular Recycling: A Lignin-Derived Semi-aromatic Biobased Polymer

Published on: November 30, 2020

Depolymerizable Olefinic Polymers Based on Fused-Ring Cyclooctene Monomers
08:12

Depolymerizable Olefinic Polymers Based on Fused-Ring Cyclooctene Monomers

Published on: December 16, 2022

Area of Science:

  • Materials Science
  • Computer Science
  • Environmental Science

Background:

  • Increasing global polymer production necessitates sustainable solutions for consumption, production, and disposal.
  • Biodegradable and bio-based polymers offer promising avenues to mitigate plastic pollution and resource depletion.
  • Effective polymer classification is crucial for advancing materials research and recycling strategies.

Purpose of the Study:

  • To develop and evaluate a novel ensemble deep learning model for accurate polymer-type classification.
  • To investigate the impact of feature selection using heuristic optimization on classification performance.
  • To assess the model's effectiveness under limited and unbalanced data conditions.

Main Methods:

  • The study introduces the New Polymers Frontier in Recycling and Sustainability Using an Ensemble of Deep Learning with a Heuristic Search Algorithm (NPFRS-EDLHSA).
  • The NPFRS-EDLHSA model integrates bidirectional recurrent neural network (BiRNN), bidirectional gated recurrent unit (BiGRU), and graph autoencoder (GAE) techniques.
  • Hyperparameter optimization is performed using the grasshopper optimization algorithm (GOA) for enhanced classification.

Main Results:

  • The NPFRS-EDLHSA model demonstrated superior performance in polymer-type classification compared to existing methods.
  • Feature selection with heuristic optimization positively influenced classification accuracy, particularly under data limitations.
  • The ensemble deep learning approach proved effective for classifying polymers on small, unbalanced datasets.

Conclusions:

  • The NPFRS-EDLHSA model provides a robust methodological framework for computational polymer typology.
  • This approach facilitates downstream materials research by improving polymer classification accuracy.
  • The findings highlight the potential of advanced machine learning techniques in addressing challenges in polymer sustainability and recycling.