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Main Authors: Yao, Jiali, Das, Uschuas Dipta, Safari, Hamid, Laskar, Md Ashiqur Rahman, Yeom, Junghoon, Celano, Umberto, Kang, Wonmo
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.04304
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author Yao, Jiali
Das, Uschuas Dipta
Safari, Hamid
Laskar, Md Ashiqur Rahman
Yeom, Junghoon
Celano, Umberto
Kang, Wonmo
author_facet Yao, Jiali
Das, Uschuas Dipta
Safari, Hamid
Laskar, Md Ashiqur Rahman
Yeom, Junghoon
Celano, Umberto
Kang, Wonmo
contents Copper-graphene composite (CGC) conductors are widely considered as a potential alternative to pure copper (Cu). Yet, the effect of graphene (Gr) on the electrical conductivity of CGCs remains elusive, and their electrical performance is still controversial. This work addresses these unresolved questions by unambiguously quantifying how the electrical properties of CGCs depend on the characteristics of Gr and Cu. Gr is synthesized on Cu foils, foams, and wires by utilizing a wide range of chemical vapor deposition conditions to independently control their characteristics. Then the Gr-enhanced electrical conductivity (Δσ) is characterized for CGCs with different Cu geometries and Gr qualities. This study confirms that unprecedented electrical conductivity (Δσ = 17.1%) can be achieved only when both Gr and Cu are carefully optimized. Specifically, the study reveals three key factors: (1) Δσ is positively correlated with continuity of Gr; (2) CGCs with a continuous monolayer Gr exhibit a strong Δσ-A_s linear relation where A_s is the specific surface area of a CGC; and (3) Δσ becomes more pronounced when a Cu matrix has a curved cross-section. This work reveals the fundamental mechanisms of how Gr influences the overall electrical conductivity of CGCs and, therefore, is a crucial step toward designing and manufacturing high-performance CGC conductors for emerging applications.
format Preprint
id arxiv_https___arxiv_org_abs_2512_04304
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Electrical Conductivity of Copper-Graphene (Cu-Gr) Composites: The Underlying Mechanisms of Ultrahigh Conductivity
Yao, Jiali
Das, Uschuas Dipta
Safari, Hamid
Laskar, Md Ashiqur Rahman
Yeom, Junghoon
Celano, Umberto
Kang, Wonmo
Materials Science
Copper-graphene composite (CGC) conductors are widely considered as a potential alternative to pure copper (Cu). Yet, the effect of graphene (Gr) on the electrical conductivity of CGCs remains elusive, and their electrical performance is still controversial. This work addresses these unresolved questions by unambiguously quantifying how the electrical properties of CGCs depend on the characteristics of Gr and Cu. Gr is synthesized on Cu foils, foams, and wires by utilizing a wide range of chemical vapor deposition conditions to independently control their characteristics. Then the Gr-enhanced electrical conductivity (Δσ) is characterized for CGCs with different Cu geometries and Gr qualities. This study confirms that unprecedented electrical conductivity (Δσ = 17.1%) can be achieved only when both Gr and Cu are carefully optimized. Specifically, the study reveals three key factors: (1) Δσ is positively correlated with continuity of Gr; (2) CGCs with a continuous monolayer Gr exhibit a strong Δσ-A_s linear relation where A_s is the specific surface area of a CGC; and (3) Δσ becomes more pronounced when a Cu matrix has a curved cross-section. This work reveals the fundamental mechanisms of how Gr influences the overall electrical conductivity of CGCs and, therefore, is a crucial step toward designing and manufacturing high-performance CGC conductors for emerging applications.
title Electrical Conductivity of Copper-Graphene (Cu-Gr) Composites: The Underlying Mechanisms of Ultrahigh Conductivity
topic Materials Science
url https://arxiv.org/abs/2512.04304