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Polymer Classification: Stereospecificity01:26

Polymer Classification: Stereospecificity

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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...
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Polymer Classification: Architecture01:14

Polymer Classification: Architecture

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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...
3.1K
Characteristics and Nomenclature of Homopolymers01:00

Characteristics and Nomenclature of Homopolymers

3.4K
Polymers that are made up of identical monomer units are called homopolymers. Only one repeating unit is involved in the construction of the homopolymer structure. For example, as depicted in Figure 1, polypropylene is a homopolymer constituted of propylene monomers. Here, the only repeating unit in the polymer chain is propylene.
3.4K
Polymer Classification: Crystallinity01:21

Polymer Classification: Crystallinity

3.2K
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...
3.2K
Molecular Weight of Step-Growth Polymers01:08

Molecular Weight of Step-Growth Polymers

2.4K
Step growth polymerization involves bi or multifunctional monomers. Bifunctional monomers react to form linear step growth polymers, whereas multifunctional monomers react to form non-linear or branched polymers.
As the step-growth polymerization involves step-wise condensation of monomers, the molecular weight also builds up eventually. Consequently, high molecular weight polymers are obtained at the late stages of the polymerization, where 99% of monomers have been consumed.
The extent of the...
2.4K
Characteristics and Nomenclature of Copolymers01:24

Characteristics and Nomenclature of Copolymers

2.8K
Copolymers are the products obtained from the polymerization of multiple monomer species. So, in a polymer chain itself, there can be multiple repeating units that come from different monomers. The process of synthesizing a polymer from different monomer species is called copolymerization. When two monomers are involved, the polymer is known as a bipolymer. Polymers with three and four monomers are termed terpolymers and quaterpolymers, respectively. Figure 1 depicts the copolymerization of...
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Updated: Oct 7, 2025

Disentangling High Strength Copolymer Aramid Fibers to Enable the Determination of Their Mechanical Properties
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Disentangling High Strength Copolymer Aramid Fibers to Enable the Determination of Their Mechanical Properties

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Structure-Property Relationship in Melt-Spun Poly(hydroxybutyrate-co-3-hexanoate) Monofilaments.

Figen Selli1,2, Rudolf Hufenus2, Ali Gooneie2

  • 1Department of Textile Engineering, Dokuz Eylul University, Izmir 35397, Turkey.

Polymers
|January 11, 2022
PubMed
Summary

This study developed a scalable melt-spinning process for biodegradable Poly(hydroxybutyrate-co-3-hexanoate) (PHBH) filaments. Optimized processing achieved high tensile strength, demonstrating PHBH

Keywords:
melt-spinningpoly(hydroxybutyrate-co-3-hexanoate) (PHBH)structure-property relationship

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Area of Science:

  • Polymer Science
  • Materials Science
  • Biomaterials Engineering

Background:

  • Poly(hydroxybutyrate-co-3-hexanoate) (PHBH) is a biodegradable polyester with potential in textiles and medicine.
  • Existing methods for producing fine PHBH filaments often require complex post-processing steps.
  • There is a need for scalable and efficient methods to produce high-performance PHBH fibers.

Purpose of the Study:

  • To develop an upscalable melt-spinning method for producing fine biodegradable PHBH filaments.
  • To investigate the influence of polymer grades and processing parameters on filament properties.
  • To correlate structural characteristics with mechanical performance.

Main Methods:

  • Melt-spinning and online drawing of PHBH monofilaments (< 130 µm diameter) from three different polymer grades.
  • Characterization of polymer grades (thermal, rheological) and filaments (morphological, thermal, mechanical, structural).
  • Analysis using wide-angle X-ray diffraction (WAXS) and small-angle X-ray scattering (SAXS).

Main Results:

  • Successful melt-spinning and online drawing of PHBH filaments from various polymer grades.
  • Achieved tensile strengths up to 291 MPa.
  • Identified a synergistic interaction between oriented non-crystalline mesophase and oriented α-crystals contributing to high tensile strength.
  • Investigated the impact of aging on structure and tensile performance.

Conclusions:

  • An upscalable melt-spinning process for fine biodegradable PHBH filaments was successfully developed.
  • High tensile strength in PHBH filaments is linked to a specific crystalline and mesophase structure.
  • The findings support the use of PHBH in demanding textile and medical applications requiring high mechanical performance.