Hierarchically Structured Vitrimer Biocomposites for Sustainable Manufacturing

Sargun Singh Rohewal; Joshua T. Damron; Jiho Seo; Nihal Kanbargi; Sumit Gupta; Holly E. Humphrey; Logan T. Kearney; Ji Chang; Laurene Tetard; Amit K. Naskar

doi:10.1002/smll.202500721

Hierarchically Structured Vitrimer Biocomposites for Sustainable Manufacturing

Sargun Singh Rohewal, Joshua T. Damron, Jiho Seo, Nihal Kanbargi, Sumit Gupta, Holly E. Humphrey, Logan T. Kearney, Ji Chang, Laurene Tetard, Amit K. Naskar

Carbon and Composites

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

Polymers containing dynamic covalent bonds (DCBs) exhibit thermoplastic-like flow above their topology freezing temperature (T_v) while maintaining thermoset-like properties below it, making them promising for sustainable manufacturing. However, their large-scale adoption remains limited due to challenges in accurately determining T_v and achieving efficient fiber-matrix bonding in composite applications. Here, hierarchically structured epoxy-anhydride-based polyester vitrimer composites reinforced with cellulosic filaments is demonstrated, where hydroxyl groups on fiber surfaces participate directly in transesterification with the matrix. This dynamic interfacial bonding delivers exceptional mechanical properties, including ≈70 MPa shear strength and >10% strain-to-failure, while enabling thermal malleability. Using a combination of nuclear magnetic resonance and nano-infrared spectroscopies, direct evidence is provided that chemical bond exchange begins well below the conventionally measured T_v, supporting the hypothesis that rheologically determined T_v reflects a combination of chemical exchange and frictional dynamics rather than a discrete transition. The composites demonstrate excellent processability through vacuum-assisted resin transfer molding and maintain >90% of their mechanical properties after multiple thermal reforming cycles. These findings advance both the fundamental understanding of vitrimeric transitions and the practical development of sustainable, high-performance composite materials.

Original language	English
Article number	2500721
Journal	Small
Volume	21
Issue number	33
DOIs	https://doi.org/10.1002/smll.202500721
State	Published - Aug 21 2025

Funding

This work was supported by the U.S. Department of Energy, Office of Science, Basic Energy Sciences, Materials Sciences and Engineering Division [FWP# ERKCK60] under contract DE-AC05-00OR22725 with UT-Battelle, LLC. S.S.R. acknowledges doctoral research scholarship through the Graduate Advancement & Training Education (GATE) fellowship awarded by University of Tennessee – Oak Ridge Innovation Institute (UT-ORII). This work was supported by the U.S. Department of Energy, Office of Science, Basic Energy Sciences, Materials Sciences and Engineering Division [FWP# ERKCK60] under contract DE‐AC05‐00OR22725 with UT‐Battelle, LLC. S.S.R. acknowledges doctoral research scholarship through the Graduate Advancement & Training Education (GATE) fellowship awarded by University of Tennessee – Oak Ridge Innovation Institute (UT‐ORII).

Keywords

low-field NMR
manufacturability
nano-IR
noninvasive spectroscopy
reversible interfacial bonding
vitrimer biocomposite

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10.1002/smll.202500721

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title = "Hierarchically Structured Vitrimer Biocomposites for Sustainable Manufacturing",

abstract = "Polymers containing dynamic covalent bonds (DCBs) exhibit thermoplastic-like flow above their topology freezing temperature (Tv) while maintaining thermoset-like properties below it, making them promising for sustainable manufacturing. However, their large-scale adoption remains limited due to challenges in accurately determining Tv and achieving efficient fiber-matrix bonding in composite applications. Here, hierarchically structured epoxy-anhydride-based polyester vitrimer composites reinforced with cellulosic filaments is demonstrated, where hydroxyl groups on fiber surfaces participate directly in transesterification with the matrix. This dynamic interfacial bonding delivers exceptional mechanical properties, including ≈70 MPa shear strength and >10\% strain-to-failure, while enabling thermal malleability. Using a combination of nuclear magnetic resonance and nano-infrared spectroscopies, direct evidence is provided that chemical bond exchange begins well below the conventionally measured Tv, supporting the hypothesis that rheologically determined Tv reflects a combination of chemical exchange and frictional dynamics rather than a discrete transition. The composites demonstrate excellent processability through vacuum-assisted resin transfer molding and maintain >90\% of their mechanical properties after multiple thermal reforming cycles. These findings advance both the fundamental understanding of vitrimeric transitions and the practical development of sustainable, high-performance composite materials.",

keywords = "low-field NMR, manufacturability, nano-IR, noninvasive spectroscopy, reversible interfacial bonding, vitrimer biocomposite",

author = "Rohewal, \{Sargun Singh\} and Damron, \{Joshua T.\} and Jiho Seo and Nihal Kanbargi and Sumit Gupta and Humphrey, \{Holly E.\} and Kearney, \{Logan T.\} and Ji Chang and Laurene Tetard and Naskar, \{Amit K.\}",

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AU - Rohewal, Sargun Singh

AU - Damron, Joshua T.

AU - Seo, Jiho

AU - Kanbargi, Nihal

AU - Gupta, Sumit

AU - Humphrey, Holly E.

AU - Kearney, Logan T.

AU - Chang, Ji

AU - Tetard, Laurene

AU - Naskar, Amit K.

PY - 2025/8/21

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N2 - Polymers containing dynamic covalent bonds (DCBs) exhibit thermoplastic-like flow above their topology freezing temperature (Tv) while maintaining thermoset-like properties below it, making them promising for sustainable manufacturing. However, their large-scale adoption remains limited due to challenges in accurately determining Tv and achieving efficient fiber-matrix bonding in composite applications. Here, hierarchically structured epoxy-anhydride-based polyester vitrimer composites reinforced with cellulosic filaments is demonstrated, where hydroxyl groups on fiber surfaces participate directly in transesterification with the matrix. This dynamic interfacial bonding delivers exceptional mechanical properties, including ≈70 MPa shear strength and >10% strain-to-failure, while enabling thermal malleability. Using a combination of nuclear magnetic resonance and nano-infrared spectroscopies, direct evidence is provided that chemical bond exchange begins well below the conventionally measured Tv, supporting the hypothesis that rheologically determined Tv reflects a combination of chemical exchange and frictional dynamics rather than a discrete transition. The composites demonstrate excellent processability through vacuum-assisted resin transfer molding and maintain >90% of their mechanical properties after multiple thermal reforming cycles. These findings advance both the fundamental understanding of vitrimeric transitions and the practical development of sustainable, high-performance composite materials.

AB - Polymers containing dynamic covalent bonds (DCBs) exhibit thermoplastic-like flow above their topology freezing temperature (Tv) while maintaining thermoset-like properties below it, making them promising for sustainable manufacturing. However, their large-scale adoption remains limited due to challenges in accurately determining Tv and achieving efficient fiber-matrix bonding in composite applications. Here, hierarchically structured epoxy-anhydride-based polyester vitrimer composites reinforced with cellulosic filaments is demonstrated, where hydroxyl groups on fiber surfaces participate directly in transesterification with the matrix. This dynamic interfacial bonding delivers exceptional mechanical properties, including ≈70 MPa shear strength and >10% strain-to-failure, while enabling thermal malleability. Using a combination of nuclear magnetic resonance and nano-infrared spectroscopies, direct evidence is provided that chemical bond exchange begins well below the conventionally measured Tv, supporting the hypothesis that rheologically determined Tv reflects a combination of chemical exchange and frictional dynamics rather than a discrete transition. The composites demonstrate excellent processability through vacuum-assisted resin transfer molding and maintain >90% of their mechanical properties after multiple thermal reforming cycles. These findings advance both the fundamental understanding of vitrimeric transitions and the practical development of sustainable, high-performance composite materials.

KW - low-field NMR

KW - manufacturability

KW - nano-IR

KW - noninvasive spectroscopy

KW - reversible interfacial bonding

KW - vitrimer biocomposite

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Hierarchically Structured Vitrimer Biocomposites for Sustainable Manufacturing

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