The ability to fabricate graphene based technology is continuing to advance and is rewarding us with a very flexible palette of options. I do expect to see flexible displays sooner than expected. Better yet, i think this will be ideal for 3D technology.
Can you imagine embedded processors supporting a holograph display. That now looks plausible.
The advance in nano based single atomic layer technology in the past decade has been breathtaking.
I waited literally forty years for us to be able to manipulate films of a single layer because i expected it to completely rewrite materials engineering. My dreams are now coming to fruition.
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Flexible graphene-based LED clears the way for flexible displays
Researchers have created a new graphene-based flexible LED
display prototype (not pictured) that is incredibly thin and bright and
could be used in next-gen mobile phones, tablets and TVs (Image:
http://www.gizmag.com/graphene-led-display-flexible-electronics/35884/
Researchers from the University of Manchester and University of
Sheffield have developed a new prototype semi-transparent,
graphene-based LED device that could form the basis of flexible screens
for use in the next-generation of mobile phones, tablets and
televisions. The incredibly thin display was created using sandwiched
"heterostructures", is only 10-40 atoms thick and emits a sheet of light
across its entire surface.
The University of Manchester has a long history of working with graphene,
with Sir Andre Geim and Sir Kostya Novoselov first isolating the
material of single-atom thickness at the University via mechanical
exfoliation (using adhesive tape) back in 2004. Since then, research has
also branched out into other promising 2D material structures,
including boron nitiride and molybdenum disulphide.
The culmination of these areas of experimentation is the new 2D LED
semiconductor built by a team led by Novoselov using a combination of
metallic graphene, insulating hexagonal boron nitride and various
semiconducting monolayers. It is this construction using LEDs engineered
at an atomic level that allowed the team to produce their breakthrough
device. As such, the work shows that graphene (combined with other
flexible 2D materials) is not just limited to simple electronic displays,
but could be exploited to create light emitting devices that are not
only incredibly thin, but flexible, semi-transparent, and intrinsically
bright.
"By preparing the heterostructures on elastic and transparent
substrates, we show that they can provide the basis for flexible and
semi-transparent electronics," said Novoselov.
This inherent elasticity and translucence also means that the device
shows promise as an alternative to current LCD or conventional LED
technology, potentially offering everything from modest lighting
products to multifaceted graphical displays.
"We envisage a new generation of optoelectronic devices to stem from
this work, from simple transparent lighting and lasers and to more
complex applications," said Freddie Withers, Royal Academy of
Engineering Research Fellow at The University of Manchester.
The heterostructures (or van der Waals
heterostructures, to give them their full name) are made by joining
different materials, usually in layers, and with the materials joined
directly at the atomic level. The heterostructures used in the new
device essentially create an electron attractive force that the
researchers have used to construct quantum wells to control the movement of electrons and make the device emit light.
In effect, these quantum wells (where electrons and "holes" both see a
lower energy in the "well" layer, hence the name) use their special
properties for the confinement of charge carriers (the electrons and
holes) in thin layers at a quantum level. A subsequent change in energy
states as exchanges are made in potential produces photons and,
therefore, light.
"The range of functionalities for the demonstrated heterostructures
is expected to grow further on increasing the number of available 2D
crystals and improving their electronic quality," said Novoselov.
According to the researchers, the reliability and stability of the
materials in the prototype device also shows promise for future
commercial manufacturing and applications.
"The novel LED structures are robust and show no significant change
in performance over many weeks of measurements," added Professor
Alexander Tartakovskii, from The University of Sheffield. "Despite the
early days in the raw materials manufacture, the quantum efficiency
(photons emitted per electron injected) is already comparable to organic
LEDs."
The research was recently published in the journal Nature Materials.
Source: University of Manchester
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