Thermal decomposition kinetics and mechanical analysis of boron carbide‐reinforced polymer nanocomposites

In the present study, the mechanical properties and thermal degradation kinetics of PVA/PVP/PEO (polyvinyl alcohol/polyvinyl pyrrolidone/polyethylene oxide) blend, along with their composites containing various percentages of boron carbide (B4C), are examined. The solvent‐casting method is used for...

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Published inPolymer engineering and science Vol. 65; no. 5; pp. 2308 - 2322
Main Authors Yildirim, Yeliz, Saltan, Fehmi, Şirin, Kamil, Küçük, Vedat Arda
Format Journal Article
LanguageEnglish
Published Hoboken, USA John Wiley & Sons, Inc 01.05.2025
Society of Plastics Engineers, Inc
Blackwell Publishing Ltd
Subjects
Activation energy
Algorithms
Analysis
Boron carbide
Carbides
chemometric analysis
Clustering
composites
DMA
Dynamic mechanical analysis
Founding
Homogeneity
Kinetics
Mechanical properties
Modulus of elasticity
Nanocomposites
Polyethylene oxide
Polymer industry
Polymers
Polyvinyl alcohol
Thermal decomposition
thermal decomposition kinetics
Thermal degradation
Thermal stability
Turkey
Online AccessGet full text
ISSN0032-3888
1548-2634
DOI10.1002/pen.27148

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Abstract In the present study, the mechanical properties and thermal degradation kinetics of PVA/PVP/PEO (polyvinyl alcohol/polyvinyl pyrrolidone/polyethylene oxide) blend, along with their composites containing various percentages of boron carbide (B4C), are examined. The solvent‐casting method is used for preparing the composites. Thermal degradation is analyzed using both Kissinger and FWO (Flynn‐Wall‐Ozawa) methods to determine the activation energies (Ea). The Ea varied with the B4C content, with higher B4C percentages leading to increased thermal stability. Dynamic mechanical analysis (DMA) was employed to evaluate the mechanical properties, revealing that B4C addition enhances the Young's modulus (E) while decreasing strain. The highest strain (ε) was observed in the PVA/PEO/PVP blend, reaching 184%. The ε values for PVA/PEO/PVP‐B4C%5, PVA/PEO/PVP‐B4C%10, and PVA/PEO/PVP‐B4C%20 composites were determined as 45.30%, 29.15%, and 16.48%, respectively. The E was measured as 0.12 MPa for PVA/PEO/PVP, while the highest E value of 0.64 MPa was observed in the PVA/PVP/PEO‐B4C20% composite. Additionally, chemometric analysis using FTIR data and clustering algorithms confirmed the homogeneity of the blends. These findings indicate that B4C‐reinforced PVA/PVP/PEO composites could serve as alternatives to conventional polymers, particularly in applications requiring enhanced thermal and mechanical stability. Highlights B4C addition increases the thermal stability of the PVA/PVP/PEO blend. DMA analysis shows that B4C addition increases the elastic modulus. Activation energies were calculated by the Kissinger and FWO methods. PVA/PVP/PEO‐B4C composites offer superior mechanical resistance. Schematic Representation of the Formation and Proposed Mechanism.
AbstractList In the present study, the mechanical properties and thermal degradation kinetics of PVA/PVP/PEO (polyvinyl alcohol/polyvinyl pyrrolidone/polyethylene oxide) blend, along with their composites containing various percentages of boron carbide ([B.sub.4]C), are examined. The solvent-casting method is used for preparing the composites. Thermal degradation is analyzed using both Kissinger and FWO (Flynn-Wall-Ozawa) methods to determine the activation energies (Ea). The Ea varied with the [B.sub.4]C content, with higher [B.sub.4]C percentages leading to increased thermal stability. Dynamic mechanical analysis (DMA) was employed to evaluate the mechanical properties, revealing that [B.sub.4]C addition enhances the Young's modulus (E) while decreasing strain. The highest strain (e) was observed in the PVA/PEO/PVP blend, reaching 184%. The e values for PVA/PEO/PVP-[B.sub.4] [C.sub.%5], PVA/PEO/PVP-[B.sub.4] [C.sub.%10], and PVA/PEO/PVP-[B.sub.4] [C.sub.%20] composites were determined as 45.30%, 29.15%, and 16.48%, respectively. The E was measured as 0.12 MPa for PVA/PEO/PVP, while the highest E value of 0.64 MPa was observed in the PVA/PVP/PEO-[B.sub.4] [C.sub.20%] composite. Additionally, chemometric analysis using FTIR data and clustering algorithms confirmed the homogeneity of the blends. These findings indicate that [B.sub.4]C- reinforced PVA/PVP/PEO composites could serve as alternatives to conventional polymers, particularly in applications requiring enhanced thermal and mechanical stability.
In the present study, the mechanical properties and thermal degradation kinetics of PVA/PVP/PEO (polyvinyl alcohol/polyvinyl pyrrolidone/polyethylene oxide) blend, along with their composites containing various percentages of boron carbide (B4C), are examined. The solvent‐casting method is used for preparing the composites. Thermal degradation is analyzed using both Kissinger and FWO (Flynn‐Wall‐Ozawa) methods to determine the activation energies (Ea). The Ea varied with the B4C content, with higher B4C percentages leading to increased thermal stability. Dynamic mechanical analysis (DMA) was employed to evaluate the mechanical properties, revealing that B4C addition enhances the Young's modulus (E) while decreasing strain. The highest strain (ε) was observed in the PVA/PEO/PVP blend, reaching 184%. The ε values for PVA/PEO/PVP‐B4C%5, PVA/PEO/PVP‐B4C%10, and PVA/PEO/PVP‐B4C%20 composites were determined as 45.30%, 29.15%, and 16.48%, respectively. The E was measured as 0.12 MPa for PVA/PEO/PVP, while the highest E value of 0.64 MPa was observed in the PVA/PVP/PEO‐B4C20% composite. Additionally, chemometric analysis using FTIR data and clustering algorithms confirmed the homogeneity of the blends. These findings indicate that B4C‐reinforced PVA/PVP/PEO composites could serve as alternatives to conventional polymers, particularly in applications requiring enhanced thermal and mechanical stability. Highlights B4C addition increases the thermal stability of the PVA/PVP/PEO blend. DMA analysis shows that B4C addition increases the elastic modulus. Activation energies were calculated by the Kissinger and FWO methods. PVA/PVP/PEO‐B4C composites offer superior mechanical resistance. Schematic Representation of the Formation and Proposed Mechanism.
In the present study, the mechanical properties and thermal degradation kinetics of PVA/PVP/PEO (polyvinyl alcohol/polyvinyl pyrrolidone/polyethylene oxide) blend, along with their composites containing various percentages of boron carbide ([B.sub.4]C), are examined. The solvent-casting method is used for preparing the composites. Thermal degradation is analyzed using both Kissinger and FWO (Flynn-Wall-Ozawa) methods to determine the activation energies (Ea). The Ea varied with the [B.sub.4]C content, with higher [B.sub.4]C percentages leading to increased thermal stability. Dynamic mechanical analysis (DMA) was employed to evaluate the mechanical properties, revealing that [B.sub.4]C addition enhances the Young's modulus (E) while decreasing strain. The highest strain (e) was observed in the PVA/PEO/PVP blend, reaching 184%. The e values for PVA/PEO/PVP-[B.sub.4] [C.sub.%5], PVA/PEO/PVP-[B.sub.4] [C.sub.%10], and PVA/PEO/PVP-[B.sub.4] [C.sub.%20] composites were determined as 45.30%, 29.15%, and 16.48%, respectively. The E was measured as 0.12 MPa for PVA/PEO/PVP, while the highest E value of 0.64 MPa was observed in the PVA/PVP/PEO-[B.sub.4] [C.sub.20%] composite. Additionally, chemometric analysis using FTIR data and clustering algorithms confirmed the homogeneity of the blends. These findings indicate that [B.sub.4]C- reinforced PVA/PVP/PEO composites could serve as alternatives to conventional polymers, particularly in applications requiring enhanced thermal and mechanical stability. Highlights * [B.sub.4]C addition increases the thermal stability of the PVA/PVP/PEO blend. * DMA analysis shows that [B.sub.4]C addition increases the elastic modulus. * Activation energies were calculated by the Kissinger and FWO methods. * PVA/PVP/PEO-[B.sub.4]C composites offer superior mechanical resistance. KEYWORDS boron carbide, chemometric analysis, composites, DMA, thermal decomposition kinetics
In the present study, the mechanical properties and thermal degradation kinetics of PVA/PVP/PEO (polyvinyl alcohol/polyvinyl pyrrolidone/polyethylene oxide) blend, along with their composites containing various percentages of boron carbide (B4C), are examined. The solvent‐casting method is used for preparing the composites. Thermal degradation is analyzed using both Kissinger and FWO (Flynn‐Wall‐Ozawa) methods to determine the activation energies (Ea). The Ea varied with the B4C content, with higher B4C percentages leading to increased thermal stability. Dynamic mechanical analysis (DMA) was employed to evaluate the mechanical properties, revealing that B4C addition enhances the Young's modulus (E) while decreasing strain. The highest strain (ε) was observed in the PVA/PEO/PVP blend, reaching 184%. The ε values for PVA/PEO/PVP‐B4C%5, PVA/PEO/PVP‐B4C%10, and PVA/PEO/PVP‐B4C%20 composites were determined as 45.30%, 29.15%, and 16.48%, respectively. The E was measured as 0.12 MPa for PVA/PEO/PVP, while the highest E value of 0.64 MPa was observed in the PVA/PVP/PEO‐B4C20% composite. Additionally, chemometric analysis using FTIR data and clustering algorithms confirmed the homogeneity of the blends. These findings indicate that B4C‐reinforced PVA/PVP/PEO composites could serve as alternatives to conventional polymers, particularly in applications requiring enhanced thermal and mechanical stability.HighlightsB4C addition increases the thermal stability of the PVA/PVP/PEO blend.DMA analysis shows that B4C addition increases the elastic modulus.Activation energies were calculated by the Kissinger and FWO methods.PVA/PVP/PEO‐B4C composites offer superior mechanical resistance.
Audience Academic
Author Küçük, Vedat Arda
Yildirim, Yeliz
Şirin, Kamil
Saltan, Fehmi
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  organization: Manisa Celal Bayar University
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  surname: Küçük
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Snippet In the present study, the mechanical properties and thermal degradation kinetics of PVA/PVP/PEO (polyvinyl alcohol/polyvinyl pyrrolidone/polyethylene oxide)...
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SubjectTerms Activation energy
Algorithms
Analysis
Boron carbide
Carbides
chemometric analysis
Clustering
composites
DMA
Dynamic mechanical analysis
Founding
Homogeneity
Kinetics
Mechanical properties
Modulus of elasticity
Nanocomposites
Polyethylene oxide
Polymer industry
Polymers
Polyvinyl alcohol
Thermal decomposition
thermal decomposition kinetics
Thermal degradation
Thermal stability
Title Thermal decomposition kinetics and mechanical analysis of boron carbide‐reinforced polymer nanocomposites
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fpen.27148
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Volume 65
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