Breakthrough in ultra-fast data processing at nanoscale

Advances in nanoelectronics are being driven by the need to shrink the size of electronic devices in a bid to produce smaller, faster and smarter gadgets and while most advanced electronic devices are powered by photonics – which involves the use of photons to transmit information – photonic elements are usually large in size limiting their use in advanced nanoelectronics systems.

Plasmons, which are waves of electrons that move along the surface of a metal after it is struck by photons, holds great promise, according to the research team, for disruptive technologies in nanoelectronics. Comparable to photons in terms of speed (they also travel with the speed of light), they are much smaller and it is this unique property which makes plasmons suitable for integration with nanoelectronics.

Earlier attempts to harness plasmons as information carriers had little success but the NUS research team has invented al “converter” that can harness the speed and small size of plasmons for high frequency data processing and transmission in nanoelectronics.

“This innovative transducer can directly convert electrical signals into plasmonic signals, and vice versa, in a single step. By bridging plasmonics and nanoscale electronics, we can potentially make chips run faster and reduce power losses. Our plasmonic-electronic transducer is about 10,000 times smaller than optical elements and we believe it can be readily integrated into existing technologies and can potentially be used in a wide range of applications in the future,” explained Associate Professor Christian Nijhuis from the Department of Chemistry at the NUS Faculty of Science, who is the leader of the research team behind this breakthrough.

In most techniques in plasmonics, plasmons are excited in two steps – electrons are used to generate light, which in turn is used to excite plasmons. To convert electrical signals into plasmonic signals, and vice versa, in one single step, the NUS team employed a process called tunnelling, in which electrons travel from one electrode to another electrode, and by doing so, excite plasmons.

“The two-step process is time-consuming and inefficient. Our technology provides a one-stop solution for the conversion electrical signals to plasmonic signals. This can be achieved without a light source, which requires multiple-steps and large optical elements, complicating integration with nanoelectronics. Based on our lab experiments, the electron-to-plasmon conversion has an efficiency of more than 10 per cent, more than 1,000 times higher than previously reported,” added Assoc Prof Nijhuis, who is also from the NUS Centre for Advanced 2D Materials and NUS Nanoscience and Nanotechnology Institute.

This work was conducted in collaboration with Dr Chu Hong Son from the Institute of High Performance Computing under the Agency for Science, Technology and Research.

The research team has filed four patents for their invention, and is collaborating with industry partners to integrate the plasmonic-electronic “converters” with existing technologies.

Further studies are planned to reduce the size of the device so that it can operate at much higher frequencies. The team is also working on integrating the transducers with more efficient plasmonic waveguides for better performance.