Mu CAO, et al. : Graphene-Copper Conductors -- Articles &
patents

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**Mu CAO, *et al.***  
**Graphene-Metal
Conductors**



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[**https://ui.adsabs.harvard.edu/abs/2019AdvFM..2906792C/abstract**](https://ui.adsabs.harvard.edu/abs/2019AdvFM..2906792C/abstract)**Ultrahigh Electrical Conductivity of Graphene
Embedded in Metals****Cao, Mu, et al****Abstract** -- Highly efficient conductors are strongly
desired because they can lead to higher working performance and
less energy consumption in their wide range applications.
However, the improvements on the electrical conductivities of
conventional conductors are limited, such as purification and
growing single crystal of metals. Here, by embedding graphene in
metals (Cu, Al, and Ag), the trade-off between carrier mobility
and carrier density is surmount in graphene, and realize high
electron mobility and high electron density simultaneously
through elaborate interface design and morphology control. As a
result, a maximum electrical conductivity three orders of
magnitude higher than the highest on record (more than 3,000
times higher than that of Cu) is obtained in such embedded
graphene. As a result, using the graphene as reinforcement, an
electrical conductivity as high as a117% of the International
Annealed Copper Standard and significantly higher than that of
Ag is achieved in bulk graphene/Cu composites with an extremely
low graphene volume fraction of only 0.008%. The results are of
significance when enhancing efficiency and saving energy in
electrical and electronic applications of metals, and also of
interest for fundamental researches on electron behaviors in
graphene.   
  


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[**https://advanced.onlinelibrary.wiley.com/doi/abs/10.1002/adfm.201806792**](https://advanced.onlinelibrary.wiley.com/doi/abs/10.1002/adfm.201806792)**Ultrahigh Electrical Conductivity of Graphene
Embedded in Metals****Mu Cao, Ding-Bang Xiong, Li Yang, Shuaishuai Li, Yiqun
Xie, Qiang Guo, Zhiqiang Li, Horst Adams, Jiajun Gu, Tongxiang
Fan, Xiaohui Zhang, Di Zhang****Abstract** -- Highly efficient conductors are strongly
desired because they can lead to higher working performance and
less energy consumption in their wide range applications.
However, the improvements on the electrical conductivities of
conventional conductors are limited, such as purification and
growing single crystal of metals. Here, by embedding graphene in
metals (Cu, Al, and Ag), the trade-off between carrier mobility
and carrier density is surmount in graphene, and realize high
electron mobility and high electron density simultaneously
through elaborate interface design and morphology control. As a
result, a maximum electrical conductivity three orders of
magnitude higher than the highest on record (more than 3,000
times higher than that of Cu) is obtained in such embedded
graphene. As a result, using the graphene as reinforcement, an
electrical conductivity as high as a117% of the International
Annealed Copper Standard and significantly higher than that of
Ag is achieved in bulk graphene/Cu composites with an extremely
low graphene volume fraction of only 0.008%. The results are of
significance when enhancing efficiency and saving energy in
electrical and electronic applications of metals, and also of
interest for fundamental researches on electron behaviors in
graphene.  
  
[**https://advanced.onlinelibrary.wiley.com/action/downloadSupplement?doi=10.1002%2Fadfm.201806792&file=adfm201806792-sup-0001-S1.pdf**](https://advanced.onlinelibrary.wiley.com/action/downloadSupplement?doi=10.1002%2Fadfm.201806792&file=adfm201806792-sup-0001-S1.pdf)**Supporting Information**


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[**https://advanced.onlinelibrary.wiley.com/doi/full/10.1002/adem.202401950**](https://advanced.onlinelibrary.wiley.com/doi/full/10.1002/adem.202401950)**Electrical and Thermal Conductivity of
Graphene/Copper Composites and Their Applications in
High-Efficiency Current-Carrying Conductors: A Review****Simeng Zhong, Xiaoting Zhang, Aimin Liu, Bingyi Zhang****Abstract** -- With the ongoing global energy
transition and rapid technological advancements, the demand for
high-efficiency systems in the power industry continues to grow.
As a core component of electrical energy transmission within
such systems, the enhancement of current-carrying conductor
performance has become a focal point for achieving technological
breakthroughs. However, conventional current-carrying materials,
such as copper, are increasingly constrained by inherent
performance limitations. Renowned for its exceptional
electrical, thermal, and mechanical properties, graphene has
emerged as a promising reinforcement phase for copper-based
composites, providing a pathway to overcome these limitations
and enhance material performance. This paper provides a
comprehensive review of various fabrication techniques for
graphene/copper (Gr/Cu) composites, systematically elucidates
the intrinsic mechanisms underlying their enhanced electrical
and thermal conductivity, and explores the key factors
influencing their performance. By summarizing recent research
findings and advancements in the application of high-efficiency
current-carrying conductors in the power industry, this study
offers theoretical support for the feasibility of Gr/Cu
composites in improving the efficiency and reliability of
conductors. Additionally, it provides an outlook on future
developments in performance optimization and large-scale
production of these materials to meet the application demands of
high-efficiency systems.  
  


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[**https://advanced.onlinelibrary.wiley.com/doi/full/10.1002/adfm.202407569**](https://advanced.onlinelibrary.wiley.com/doi/full/10.1002/adfm.202407569)**Effects of Graphene Doping on the Electrical
Conductivity of Copper****Chenmu Zhang, Zhongcan Xiao, Rachel Paddock, Michael
Cullinan, Mehran Tehrani, Yuanyue Liu****Abstract** -- There is great interest in developing
advanced electrical conductors with higher conductivity, lighter
weight, and higher mechanical strength than copper (Cu). One
promising candidate is copper-graphene (Cu-Gr) composite, which
is hypothesized to have a higher electrical conductivity than
Cu. In this work, it is shown that this is not true, supported
by state-of-the-art first-principles calculations of electron
transport. Particularly, contrary to the belief that graphene in
the composite is more conductive than pristine Cu, it is less
conductive due to increased scattering despite increased carrier
concentration. On the other hand, it is found that compressive
strain along the (111) plane increases the conductivity, which
is confirmed experimentally, while tensile strain has little
effect. The work offers new insights into understanding and
developing advanced conductors.  
  


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[**https://www.mdpi.com/2075-4701/15/10/1117**](https://www.mdpi.com/2075-4701/15/10/1117)**Wenjie Liu, Xingyu Zhao, Hongliang Li, Yi Ding,** **Research Progress on the Preparation and Properties of
GrapheneaCopper Composites, Metals, 10.3390/met15101117, 15,
10, (1117), (2025).****Abstract -**- The persistent conflict between strength
and electrical conductivity in copper-based materials presents a
fundamental limitation for next-generation high-performance
applications. Graphene, with its unique two-dimensional
architecture and exceptional intrinsic characteristics, has
become a promising reinforcement phase for copper matrices. This
comprehensive review synthesizes recent advancements in
grapheneacopper composites (CGCs), focusing particularly on
structural design innovations and scalable manufacturing
approaches such as powder metallurgy, molecular-level mixing,
electrochemical deposition, and chemical vapor deposition. The
analysis examines pathways for optimizing key
propertiesaincluding mechanical strength, thermal conduction,
and electrical performanceawhile investigating the fundamental
reinforcement mechanisms and charge/heat transport phenomena.
Special consideration is given to how graphene morphology,
concentration, structural quality, interfacial chemistry, and
processing conditions collectively determine composite behavior.
Significant emphasis is placed on interface engineering
strategies, graphene alignment, consolidation control, and
defect management to minimize electron and phonon scattering
while improving stress transfer efficiency. The review concludes
by proposing research directions to resolve the
strengthaconductivity paradox and broaden practical
implementation domains, thereby offering both methodological
frameworks and theoretical foundations to support the industrial
adoption of high-performance CGCs.  
  


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[**https://www.sciencedirect.com/science/article/abs/pii/S1359835X25004944?via%3Dihub**](https://www.sciencedirect.com/science/article/abs/pii/S1359835X25004944?via%3Dihub)**Composites Part A: Applied Science and
Manufacturing****Volume 199, December 2025, 109200****Constructing harmonic grain distribution in
graphene-reinforced Cu matrix composites for enhanced strength
and electrical conductivity****Junrui Huang, Jiajing Liu, Yubo Zhang, Xi Yang a, Xin
Sun, Shanhao Du, Tingju Li, Tongmin Wang****Abstract -**- Graphene-reinforced copper matrix (Gr/Cu)
composites typically exhibit high strength and electrical
conductivity, with graphene playing a vital role in enhancing
electrical conductivity. In this study, Gr/Cu composites with a
novel harmonic grain structure were fabricated via in-situ
graphene growth and hot-press sintering, and the synergistic
effects of the Gr-network and Cu grains on the conductivity were
systematically investigated. The harmonic unit consists of fine
grains surrounding coarse grains, which is constructed by
Gr-network distribution and grain growth. With an optimal
harmonic configuration, the Gr/Cu composite achieves exceptional
electrical conductivity of 102.70 % IACS, an ultimate tensile
strength of 332.64 MPa, and an elongation of 28 %. The
continuous three-dimensional Gr-network is crucial for ensuring
superior electrical conductivity. Additionally, the harmonic
structure minimizes carrier scattering and facilitates improved
electrical conductivity. The unique grain distribution in the
harmonic configuration also promotes strain delocalization and
micro-crack blunting, leading to simultaneous improvements in
physical and mechanical properties. These findings highlight the
critical role of matrix microstructure and its cascading effect
on electrical conductivity, providing a theoretical foundation
for advancing conductive mechanisms in metal matrix composites
(MMCs).  
  


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[**https://www.sciencedirect.com/science/article/abs/pii/S1359835X25004312?via%3Dihub**](https://www.sciencedirect.com/science/article/abs/pii/S1359835X25004312?via%3Dihub)**Composites Part A: Applied Science and
Manufacturing****Volume 198, November 2025, 109137****Composites Part A: Applied Science and Manufacturing****In-situ synthesis nitrogen-doped graphene/Cu composites
with enhanced mechanical and electrical properties****Changsheng Xing a, Tong Zhang, Miao Wang Zhendong Shi,
Yunzhong Wu, Jie Sheng, Lidong Wang, Weidong Fei** **Abstract** -- For graphene/metal composites, both the
synthesis of graphene and the interfacial bonding with the metal
matrix are crucial for determining overall performance. In this
study, in-situ nitrogen-doped graphene/Cu composites were
successfully fabricated using polyacrylonitrile (PAN) as the
carbon source, and the effects of PAN-derived graphene on
composite microstructure, mechanical properties, and electrical
performance were systematically investigated. The results show
that an optimal PAN content of 0.25 wt% promotes the formation
of high-quality in-situ graphene, which simultaneously
strengthens the copper matrix and improves electrical stability.
On the mechanical side, the composite showed a yield strength of
408 MPa and a tensile strength of 427 MPa, with increases of 63
% and 42 %, respectively, compared to pure copper. This
enhancement is primarily attributed to dislocation
strengthening, grain refinement, and load transfer, with
graphene reinforcing the composite by restricting dislocation
motion, impeding grain growth, and providing the intrinsic high
strength of graphene. On the electrical side, the composite
maintained a high room-temperature electrical conductivity of
94.2 % IACS while achieving a reduced temperature coefficient of
resistance (TCR) of 3.68 A 10-3 Ka1, which results from the high
intrinsic conductivity and negative TCR of graphene. These
findings highlight the dual role of PAN-derived graphene in
enhancing both the mechanical and electrical properties,
offering valuable insights into the development of
high-performance graphene/metal composites for industrial
applications.  
  


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[**https://www.sciencedirect.com/science/article/abs/pii/S1359835X24003427**](https://www.sciencedirect.com/science/article/abs/pii/S1359835X24003427)**Composites Part A: Applied Science and
Manufacturing****Volume 185, October 2024, 108345****The electrical conductivity mechanism of Graphene/Copper
composite fabricated by one-step pulsed electrodeposition****Jiani Yu, Lidong Wang, Yekang Guan , Bin Shao, Yingying
Zong** **Abstract** -- Copper plays a key role in electronics,
energy, and so on. However, copper faces the challenge of
increasing resistivity with increasing temperature. To overcome
this problem, graphene was introduced into copper to prepare
graphene/copper (Gr/Cu) composites. Here, we report on the
preparation of Gr/Cu-Cu wires and Gr/Cu foil by pulse
electrodeposition (P-EP). The electrical conductivity of the
Gr/Cu foil was 3.8 % IACS higher than that of pure Cu foil under
180 A degC. Graphene plays a crucial role in providing an electron
transfer path in the Gr/Cu composite to improve the electrical
conductivity under high temperatures. The P-EP process can not
only effectively reduce the raw GO, but also introduce nitrogen
into graphene which further promotes the transfer of electrons
from copper to graphene. These results suggest that Gr/Cu
composites have promising prospects for applications at high
temperatures and could potentially replace traditional pure Cu.  
  


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[**https://hal.science/hal-04314387v1/document**](https://hal.science/hal-04314387v1/document)**Fabrication and characterization of copper and
copper** **alloys reinforced with graphene****Antoine Bident, et al****Abstract** -- The consistent rise in current density
within electrical wires leads to progressively more substantial
heat losses attributed to the Joule effect. Consequently,
mitigating the electrical resistivity of copper wires becomes
imperative. To attain this objective, the development of a
composite material that incorporates a more conductive
reinforcement, like graphene, holds great promise. The
conception of a copper/graphene composite using a powder
metallurgy-based approach is presented. An optimum graphene
quantity of 0.06 vol.% was obtained by calculation in order to
limit the phenomenon of overlapping layers. This synthesis
technique enables the dispersion of graphene and the meticulous
control of the interface through the growth of CuO(Cu)
nanoparticles that are tightly bonded to the reinforcement. The
increase in the hardness  
of the various materials with separation of the graphene sheets
by ultrasonic treatment (55.3 to 67.6 HV) was obtained. It is an
indicator of the correct distribution of the reinforcement. The
influence on the electrical properties of dendritic copper (Ie =
2.30 I1/4V.cm) remains limited, resulting in a modest reduction in
electrical resistance of around 1.4%. Nevertheless, for flake
copper (2.71 I1/4V.cm) and brass (7.66 I1/4V.cm), we achieved a more
substantial reduction of 2.7% and 10%, respectively. With the
improvement of graphene quality, there exists a greater
potential for further enhancing the electrical properties.  
  


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**Patents**

  
**CN110079785
--** **Preparation
method of copper-based graphene composite material and
copper-based graphene composite material****[ [PDF](CN110079785A.pdf) ] [
[Translation](CN110079785transl.pdf)
]****Abstract** -- The invention provides a preparation
method of a copper-based graphene composite material. The
preparation method of the copper-based graphene composite
material comprises the following steps: pretreating an original
plate-shaped copper base by an electrochemical polishing process
to obtain a pretreated copper base, wherein the thickness of the
original plate-shaped copper base is 5 to 25 microns;growing
graphene on the upper surface and the lower surface of the
pretreated copper base by a chemical vapor deposition process to
obtain graphene coated copper bases; and performing hot pressed
sintering treatment on at least one graphene coated copper base
to obtain the copper-based graphene composite material, wherein
the copper-based graphene composite material is a layered
composite material formed by alternately compounding graphene
and the copper base, and the copper base is in a single
crystalline state in the thickness direction of the copper-based
graphene composite material and takes on predominant crystal
orientation (111). By the preparation method of the copper-based
graphene composite material provided by the invention, the
copper-based graphene composite material with high conductivity
can be prepared.  
  
**CN108149046
--** **High
strength, high conductivity graphene/copper nanocomposite
material and preparation method and application thereof****[ [PDF](CN108149046A.pdf) ]** ****[ [Translation](CN108149046A.pdf) ]******Abstract** -- The invention relates to a high
strength, high conductivity graphene/copper nanocomposite
material and a preparation method and application thereof. A
copper matrix of the composite material is uniformly distributed
in three-dimensional nanometer scale, the scale is between
10-100 nm, preferably, 30nm-80nm; and graghene is of a
three-dimensional interconnection network structure in the
composite material, and the number of average layers is 1-100.
The obtained graphene/copper nanocomposite material has the
characteristics of high strength, high modulus and high
conductivity, and can be used asvarious types of conductive
materials.  
  
**CN106584976
--** **High-conductivity
graphene/copper-based layered composite material and
preparation method thereof****[ [PDF](CN106584976A.pdf) ]** ****[ [Translation](CN106584976transl.pdf) ]******Abstract** -- The invention discloses a
high-conductivity graphene/copper-based layered composite
material and a preparation method thereof. The composite
material is characterized in that the composite material is of a
layered structure formed by alternate combination of chemical
vapor deposition (CVD) graphene and a copper substrate, the
copper substrate is in a single-crystal state in the thickness
direction in layers, and the (111) crystal face high-orientation
effect is achieved. The method includes the following steps that
(1) graphene is grown on the upper surface and the lower surface
of the platy copper substrate through a CVD technology and the
copper substrate is induced to achieve preferred orientation
along a (111) crystal face, and the sandwich-shaped
graphene-cladding copper substrate is obtained through
preparation; and (2) multiple pieces of graphene-cladding copper
substrates are subjected to hot pressed sintering densification
to form the high-conductivity graphene/copper-based layered
composite material. The layered composite material prepared by
the method is high in conductivity, higher than pure silver in
conduction level and easy to produce and can be used as various
conduction materials.  
  
**CN120553696 --  Method for preparing graphene composite
material based on catalytic modification of cerium dioxide** **[ [PDF](CN120553696A.pdf) ]** ****[ [Translation](CN120553696transl.pdf) ]******Abstract** -- The invention belongs to the technical
field of graphene preparation, and particularly discloses a
method for preparing a graphene composite material based on
catalytic modification of cerium dioxide, and the method
comprises the following steps: pretreating a copper substrate;
the preparation method comprises the following steps: adding
cerium dioxide nanoparticles and a dispersing agent into
deionized water, and then ultrasonically dispersing uniformly to
obtain a cerium dioxide suspension; immersing the pretreated
copper substrate into the cerium dioxide suspension, then
pulling the copper substrate to form a cerium dioxide coating on
the surface of the copper substrate, and then standing and
drying for later use; and S3, the copper substrate with the
cerium dioxide coating on the surface in the step S3 is placed
in a reaction chamber, then vacuumizing is conducted, the
temperature is increased to 800-1060 DEG C, meanwhile, a carbon
source, hydrogen and protective gas are introduced into the
reaction chamber, heat preservation is conducted for 10-30 min,
and therefore the graphene composite material is prepared on the
surface of the copper substrate. According to the method, the
number of active sites evenly distributed on the surface of the
copper substrate can be effectively increased, the growth rate
of the graphene is increased, the growth uniformity of the
graphene is guaranteed, meanwhile, the heat-conducting property
of the graphene can be improved, and the resistivity is reduced.  
  


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