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Constructing a parallel aligned shish kebab structure of HDPE/BN composites: Toward improved two-way thermal conductivity and tensile strength

Inspired by the clam-shell structure of pearls, we fabricated thermally conductive high-density polyethylene (HDPE) reinforced by a 2D filler, boron nitride (BN). SEM images showed only lamellae randomly distributed in unshared HDPE samples, whereas a shish-kebab structure was introduced by utilizing an in-house designed rotational shear system. XRD results indicate the BN (002) plane is parallel to the sheared direction. Due to the interconnected shish-kebab structure and aligned BN (002) plane, the Vicat softening temperature was increased from 82.8 °C to 107.9 °C, demonstrating excellent heat resistance under high temperatures. An optimal thermal conductivity of 1.26 W/mK was found at 35 vol% BN loading with a tensile strength of 40 MPa. This work has utilized external force to manufacture HDPE/BN composites with effective thermal dissipation and higher service temperature. The excellent thermo-mechanical properties mean a longer service time and less replaced frequency of material under extreme operating conditions.

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Work Title Constructing a parallel aligned shish kebab structure of HDPE/BN composites: Toward improved two-way thermal conductivity and tensile strength
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Open Access
Creators
  1. Bin Chen
  2. Jiawei Gong
  3. Wei Huang
  4. Ning Gao
  5. Cong Deng
  6. Xueqin Gao
License In Copyright (Rights Reserved)
Work Type Article
Publisher
  1. Composites Part B: Engineering
Publication Date June 15, 2023
Publisher Identifier (DOI)
  1. https://doi.org/10.1016/j.compositesb.2023.110699
Deposited November 18, 2024

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Version 1
published

  • Created

    November 18, 2024 11:49 by Researcher Metadata Database

  • Added 1-s2.0-S0266353810000035-main.pdf

    November 18, 2024 11:49 by Researcher Metadata Database

  • Added Creator Bin Chen

    November 18, 2024 11:49 by Researcher Metadata Database

  • Added Creator Jiawei Gong

    November 18, 2024 11:49 by Researcher Metadata Database

  • Added Creator Wei Huang

    November 18, 2024 11:49 by Researcher Metadata Database

  • Added Creator Ning Gao

    November 18, 2024 11:49 by Researcher Metadata Database

  • Added Creator Cong Deng

    November 18, 2024 11:49 by Researcher Metadata Database

  • Added Creator Xueqin Gao

    November 18, 2024 11:49 by Researcher Metadata Database

  • Published

    November 18, 2024 11:49 by Researcher Metadata Database

  • Updated

    November 18, 2024 21:04 by [unknown user]

Version 2
published

  • Created

    April 22, 2025 11:22 by jzg317

  • Deleted Creator Bin Chen

    April 22, 2025 11:23 by jzg317

  • Deleted Creator Jiawei Gong

    April 22, 2025 11:23 by jzg317

  • Deleted Creator Wei Huang

    April 22, 2025 11:23 by jzg317

  • Deleted Creator Ning Gao

    April 22, 2025 11:23 by jzg317

  • Deleted Creator Cong Deng

    April 22, 2025 11:23 by jzg317

  • Deleted Creator Xueqin Gao

    April 22, 2025 11:23 by jzg317

  • Added Creator Bin Chen

    April 22, 2025 11:23 by jzg317

  • Added Creator Jiawei Gong

    April 22, 2025 11:23 by jzg317

  • Added Creator Wei Huang

    April 22, 2025 11:23 by jzg317

  • Added Creator Ning Gao

    April 22, 2025 11:23 by jzg317

  • Added Creator Cong Deng

    April 22, 2025 11:23 by jzg317

  • Added Creator Xueqin Gao

    April 22, 2025 11:23 by jzg317

  • Updated Keyword, Description, Related URLs Show Changes

    April 22, 2025 11:23 by jzg317

    Keyword
    • Thermal Conductivity, Boron Nitride, Ultimate Tensile Strength, Composite Material, High Density Polyethylenes, High Density Polyethylene, Tensile Strength, Thermal Tensile, Density Polyethylene, Nitride, Polyethylene, Parallel Alignment, Density, Heat Resistance, Thermal Dissipation, Service Time, Randomly Distributed, Lamellae, High Temperature, Reinforced, Vol%, Pearl, Thermomechanical Properties, External Force, Clamshell, Shell Structures, Sem Images, Service Temperature, Thermally Conductive, Softening Temperature, Conductive, Rotational, Shells (Structures), X Ray Diffraction, Scanning Electron Microscopy, Thermomechanical Property
    Description
    • <p>Inspired by the clam-shell structure of pearls, we fabricated thermally conductive high-density polyethylene (HDPE) reinforced by a 2D filler, boron nitride (BN). SEM images showed only lamellae randomly distributed in unshared HDPE samples, whereas a shish-kebab structure was introduced by utilizing an in-house designed rotational shear system. XRD results indicate the BN (002) plane is parallel to the sheared direction. Due to the interconnected shish-kebab structure and aligned BN (002) plane, the Vicat softening temperature was increased from 82.8 °C to 107.9 °C, demonstrating excellent heat resistance under high temperatures. An optimal thermal conductivity of 1.26 W/mK was found at 35 vol% BN loading with a tensile strength of 40 MPa. This work has utilized external force to manufacture HDPE/BN composites with effective thermal dissipation and higher service temperature. The excellent thermo-mechanical properties mean a longer service time and less replaced frequency of material under extreme operating conditions.</p>
    • Inspired by the clam-shell structure of pearls, we fabricated thermally conductive high-density polyethylene (HDPE) reinforced by a 2D filler, boron nitride (BN). SEM images showed only lamellae randomly distributed in unshared HDPE samples, whereas a shish-kebab structure was introduced by utilizing an in-house designed rotational shear system. XRD results indicate the BN (002) plane is parallel to the sheared direction. Due to the interconnected shish-kebab structure and aligned BN (002) plane, the Vicat softening temperature was increased from 82.8 °C to 107.9 °C, demonstrating excellent heat resistance under high temperatures. An optimal thermal conductivity of 1.26 W/mK was found at 35 vol% BN loading with a tensile strength of 40 MPa. This work has utilized external force to manufacture HDPE/BN composites with effective thermal dissipation and higher service temperature. The excellent thermo-mechanical properties mean a longer service time and less replaced frequency of material under extreme operating conditions.
    Related URLs
    • https://scholarsphere.psu.edu/resources/9b674ced-72a4-454f-8946-68d6b7d73d06
  • Updated

    April 22, 2025 11:23 by jzg317

  • Updated

    April 22, 2025 11:23 by jzg317

  • Updated Creator Bin Chen

    April 22, 2025 11:23 by jzg317

  • Updated Creator Jiawei Gong

    April 22, 2025 11:23 by jzg317

  • Updated Creator Wei Huang

    April 22, 2025 11:23 by jzg317

  • Updated Creator Ning Gao

    April 22, 2025 11:23 by jzg317

  • Updated Creator Cong Deng

    April 22, 2025 11:23 by jzg317

  • Updated Creator Xueqin Gao

    April 22, 2025 11:23 by jzg317

  • Added 1-s2.0-S1359836823002020-main.pdf

    April 22, 2025 11:24 by jzg317

  • Deleted 1-s2.0-S0266353810000035-main.pdf

    April 22, 2025 11:25 by jzg317

  • Deleted 1-s2.0-S1359836823002020-main.pdf

    April 22, 2025 11:26 by jzg317

  • Added 1-s2.0-S1359836823002020-main.pdf

    April 22, 2025 11:27 by jzg317

  • Published

    April 22, 2025 11:27 by jzg317

  • Updated

    April 22, 2025 22:04 by [unknown user]

  • Updated Related URLs Show Changes

    April 23, 2025 09:28 by jts5573

    Related URLs
    • https://scholarsphere.psu.edu/resources/9b674ced-72a4-454f-8946-68d6b7d73d06