Graphene paves the way for world’s thinnest light bulb
The researchers attached small strips of graphene to metal electrodes, suspended the strips above the substrate, and passed a current through the filaments to cause them to heat up.
The research, which was led by Young Duck Kim, a postdoctoral research scientist in James Hone’s group at Columbia Engineering, is detailed in study entitled ‘Bright Visible Light Emission from Graphene’ and published in the Advance Online Publication (AOP) on Nature Nanotechnology’s website.
“We’ve created what is essentially the world’s thinnest light bulb,” explained Hone, Wang Fon-Jen Professor of Mechanical Engineering at Columbia Engineering and co-author of the study. “This new type of ‘broadband’ light emitter can be integrated into chips and will pave the way towards the realization of atomically thin, flexible, and transparent displays, and graphene-based on-chip optical communications.”
Creating light in small structures on the surface of a chip is crucial for developing fully integrated ‘photonic’ circuits that do with light what is now done with electric currents in semiconductor integrated circuits. Researchers have developed many approaches to do this, but have not yet been able to put the oldest and simplest artificial light source – the incandescent light bulb – onto a chip. This is primarily because light bulb filaments must be extremely hot – thousands of degrees Celsius – in order to glow in the visible range and micro-scale metal wires cannot withstand such temperatures. In addition, heat transfer from the hot filament to its surroundings is extremely efficient at the microscale, making such structures impractical and leading to damage of the surrounding chip.
By measuring the spectrum of the light emitted from the graphene, the team was able to show that the graphene was reaching temperatures of above 2500 degrees Celsius, hot enough to glow brightly. “The visible light from atomically thin graphene is so intense that it is visible even to the naked eye, without any additional magnification,” explained Young Duck Kim, first and co-lead author on the paper and postdoctoral research scientist who works in Hone’s group at Columbia Engineering.
Interestingly, the spectrum of the emitted light showed peaks at specific wavelengths, which the team discovered was due to interference between the light emitted directly from the graphene and light reflecting off the silicon substrate and passing back through the graphene. “This is only possible because graphene is transparent, unlike any conventional filament, and allows us to tune the emission spectrum by changing the distance to the substrate,” noted Kim.
The ability of graphene to achieve such high temperatures without melting the substrate or the metal electrodes is due to another interesting property: as it heats up, graphene becomes a much poorer conductor of heat. This means that the high temperatures stay confined to a small ‘hot spot’ in the center.
“At the highest temperatures, the electron temperature is much higher than that of acoustic vibrational modes of the graphene lattice, so that less energy is needed to attain temperatures needed for visible light emission,” said Myung-Ho Bae, a senior researcher at KRISS and co-lead author. “These unique thermal properties allow us to heat the suspended graphene up to half of temperature of the sun, and improve efficiency 1000 times, as compared to graphene on a solid substrate.”
The team also demonstrated the scalability of their technique by realizing large-scale of arrays of chemical-vapor-deposited (CVD) graphene light emitters.
Yun Daniel Park, professor in the department of physics and astronomy at Seoul National University and co-lead author, noted that they are working with the same material that Thomas Edison used when he invented the incandescent light bulb: “Edison originally used carbon as a filament for his light bulb and here we are going back to the same element, but using it in its pure form – graphene – and at its ultimate size limit – one atom thick.”
The group is currently working to further characterize the performance of these devices – for example, how fast they can be turned on and off to create ‘bits’ for optical communications – and to develop techniques for integrating them into flexible substrates.
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