Effect of processing routes on mechanical and thermal properties of copper–graphene composites

Faisal Nazeer; Zhuang Ma; Lihong Gao; Abdul Malik; Muhammad Abubaker Khan; Fuchi Wang; Hezhang Li

doi:10.1080/02670836.2019.1646962

Effect of processing routes on mechanical and thermal properties of copper–graphene composites

Faisal Nazeer, Zhuang Ma, Lihong Gao^*, Abdul Malik, Muhammad Abubaker Khan, Fuchi Wang, Hezhang Li

^*Corresponding author for this work

School of Material Science and Engineering

Beijing Institute of Technology

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

17 Citations (Scopus)

Abstract

In this paper, copper–graphene composites were fabricated by using two different processing routes (ball milling (BM) and ultrasonication) followed by spark plasma sintering. Vickers hardness and anisotropic thermal conductivity of the composites were measured and observed that ultrasonicated fabricated composites gave better result compared with BM composite and even from pure copper. The hardness values obtained for ultrasonicated copper–graphene composite were 69 HV (57% higher) and thermal conductivity 387 W/m K (13% higher) by using only 0.5 wt-% of graphene, while for pure copper the values were 44 HV and 341 W/m K. The value of anisotropic thermal conductivity ultrasonicated composites was also 1.97 which is much higher than pure copper 0.94.

Original language	English
Pages (from-to)	1770-1774
Number of pages	5
Journal	Materials Science and Technology
Volume	35
Issue number	14
DOIs	https://doi.org/10.1080/02670836.2019.1646962
Publication status	Published - 2019

Keywords

Copper–graphene composites
anisotropic thermal conductivity
hardness
spark plasma sintering

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10.1080/02670836.2019.1646962

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title = "Effect of processing routes on mechanical and thermal properties of copper–graphene composites",

abstract = "In this paper, copper–graphene composites were fabricated by using two different processing routes (ball milling (BM) and ultrasonication) followed by spark plasma sintering. Vickers hardness and anisotropic thermal conductivity of the composites were measured and observed that ultrasonicated fabricated composites gave better result compared with BM composite and even from pure copper. The hardness values obtained for ultrasonicated copper–graphene composite were 69 HV (57% higher) and thermal conductivity 387 W/m K (13% higher) by using only 0.5 wt-% of graphene, while for pure copper the values were 44 HV and 341 W/m K. The value of anisotropic thermal conductivity ultrasonicated composites was also 1.97 which is much higher than pure copper 0.94.",

keywords = "Copper–graphene composites, anisotropic thermal conductivity, hardness, spark plasma sintering",

author = "Faisal Nazeer and Zhuang Ma and Lihong Gao and Abdul Malik and {Abubaker Khan}, Muhammad and Fuchi Wang and Hezhang Li",

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TY - JOUR

T1 - Effect of processing routes on mechanical and thermal properties of copper–graphene composites

AU - Nazeer, Faisal

AU - Ma, Zhuang

AU - Gao, Lihong

AU - Malik, Abdul

AU - Abubaker Khan, Muhammad

AU - Wang, Fuchi

AU - Li, Hezhang

PY - 2019

Y1 - 2019

N2 - In this paper, copper–graphene composites were fabricated by using two different processing routes (ball milling (BM) and ultrasonication) followed by spark plasma sintering. Vickers hardness and anisotropic thermal conductivity of the composites were measured and observed that ultrasonicated fabricated composites gave better result compared with BM composite and even from pure copper. The hardness values obtained for ultrasonicated copper–graphene composite were 69 HV (57% higher) and thermal conductivity 387 W/m K (13% higher) by using only 0.5 wt-% of graphene, while for pure copper the values were 44 HV and 341 W/m K. The value of anisotropic thermal conductivity ultrasonicated composites was also 1.97 which is much higher than pure copper 0.94.

AB - In this paper, copper–graphene composites were fabricated by using two different processing routes (ball milling (BM) and ultrasonication) followed by spark plasma sintering. Vickers hardness and anisotropic thermal conductivity of the composites were measured and observed that ultrasonicated fabricated composites gave better result compared with BM composite and even from pure copper. The hardness values obtained for ultrasonicated copper–graphene composite were 69 HV (57% higher) and thermal conductivity 387 W/m K (13% higher) by using only 0.5 wt-% of graphene, while for pure copper the values were 44 HV and 341 W/m K. The value of anisotropic thermal conductivity ultrasonicated composites was also 1.97 which is much higher than pure copper 0.94.

KW - Copper–graphene composites

KW - anisotropic thermal conductivity

KW - hardness

KW - spark plasma sintering

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DO - 10.1080/02670836.2019.1646962

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EP - 1774

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JF - Materials Science and Technology

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ER -

Effect of processing routes on mechanical and thermal properties of copper–graphene composites

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Keywords

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