Graphene
is a disruptive technology; one that could open up new markets and even replace existing
technologies or materials. It is when graphene is used both to improve an
existing material and in a transformational capacity that its true potential
can be realised. The graphene
is a single layer (monolayer) of carbon atoms, tightly bound in a hexagonal
honeycomb lattice. It is an allotrope of carbon in the form of a plane of
sp2-bonded atoms with a molecular bond length of 0.142 nanometres. Layers of graphene stacked on top of each other form graphite, with an interplanar spacing of
0.335 nanometres. The separate layers of graphene in graphite are held together
by van der Waals forces, which can be overcome during exfoliation of graphene
from graphite.
Other notable
properties of graphene are its uniform
absorption of light across the visible and near-infrared parts of the spectrum (πα
≈ 2.3%), and its potential suitability for use in spin
transport. Bearing this in mind, one might be surprised to know that
carbon is the second most abundant mass within the human body and the fourth
most abundant element in the universe (by mass), after hydrogen, helium and
oxygen.
This
makes carbon the chemical basis for all known life on earth, making graphene
potentially an eco-friendly, sustainable solution for an almost
limitless number of applications. Since the discovery (or more
accurately, the mechanical obtainment) of graphene, applications within
different scientific disciplines have exploded, with huge gains being made
particularly in high-frequency
electronics, bio, chemical and magnetic sensors, ultra-wide
bandwidth photodetectors, and energy
storage and generation.