Graphene holds the title of the world strongest material known. It
also has soft and light weight features that makes the material unique.
These records have just been broken by a
composite known as Copper-Graphene.
Researchers at the
Korean Advanced Institute of Science and Technology (KAIST) have created composite materials using graphene that are up to 500 times stronger than the raw, non-composite material.
Korean Advanced Institute of Science and Technology (KAIST) have created composite materials using graphene that are up to 500 times stronger than the raw, non-composite material.
This is the first time that graphene has been successfully used to
create strong composite materials — and due to the tiny amounts of graphene
used (just 0.00004% by weight) this breakthrough could lead to much faster commercial
adoption than pure graphene, which is still incredibly hard to produce in large
quantities.
At this point, we shouldn’t be
wholly surprised that grapheme — which
holds a huge number of superlative titles, including the strongest material
known to man — can also be used to create strong composite materials.
In this case, the KAIST researchers created a copper-graphene composite
that has 500 times the tensile strength of copper (1.5 gigapascals), and a
nickel-grapehene composite that has180 times the tensile strength of nickel (4
gigapascals). This is still some way off graphene’s tensile strength of 130 GPa
— which is about 200 times stronger than steel (600 MPa) — but it’s still very,
very strong. At 1.5 GPa, copper-graphene is about 50% stronger than titanium,
or about three times as strong as structural aluminium alloys.
To create these composites, the KAIST researchers use a process called
CVD (chemical vapor deposition) to grow monolayers (one-atom-thick layers) of graphene.
These monolayers are then deposited onto a thin film of metal (copper or
nickel).
Another layer of metal is then evaporated (a method of deposition)
on top of the graphene. This process is repeated, until you have a sandwich
consisting of a few layers of metal and graphene.
Different metal thicknesses were tested (between 70nm and 300nm),
and it was found that thinner layers result in much stronger composites.
Because graphene is so thin, the amount used is absolutely tiny: Just 0.00004%
of the metals by weight.
The reason these composites are so strong
is that the graphene stops the metal atoms from slipping and dislocating under
stress.
In a solid metal, if a slip
plane forms (due to stress), the atoms will readily slip apart, causing a
fracture. The layers of graphene stop the metal atoms from sliding — the metal
atoms cannot physically pass through the super-strong graphene — so no
fractures can form (pictured above). It’s essentially the
metallic equivalent of steel- reinforced concrete. In case you were
wondering, this is also one of the primary reasons why metals are nearly always
used in alloy form — because there’s a mix of different metal atoms with different
atom sizes, it’s much harder for slip planes to form.
Moving forward, the researchers will now
need to find a way of mass-producing these graphene-based composites, preferably
with a roll-to-roll or metal sintering process. These composites, due to their
massive strength, could find myriad uses in the automotive and aerospace industries,
or simply as a new tool for structural engineers and industrial design. Just
the sheer fact that we now know that graphene can be used as a composite is
massive news, too:
If graphene can suddenly turn soft copper into a structural material,
imagine what it might do for something like titanium or steel, or even
commercial polymers like Kevlar.
For more on this new composite material get the Research paper: “Strengthening
effect
of single-atomic-layer graphene
in metal–graphene nanolayered
composites”
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