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Numerical and theoretical analyses describing the performance of a 2D disordered array of nanoholes in channel transfer form far-field input to SPP output

Microprocessors play a pivotal role in computers and have steadily increased the speed of information processing over the past several decades. However, due to technical limitations such as heat generation due to integration, the processing speed of semiconductors has remained at several gigahertz (GHz) for the past decade. As a current alternative to this, many microprocessors are used in parallel, but the electrical connection between the processors is slow, creating a bottleneck for data transfer. To solve this problem, many studies have been conducted to merge processors by using optical signals that are several hundred times faster than electrical signals.

A new way to connect nanoscale microprocessors to ultra-high-speed optical communications

Wonshik Choi, associate director of the from the Center for Molecular Spectroscopy and Dynamics (CMSD) at Korea’s Institute for Basic Science (IBS), lead the research team that created an innovative device. The team discarded the conventional method of periodically arranging the nano-antennas. Instead, they devised disordered arrangement of the antennas to minimize redundancy between the antennas and enabled each antenna to function independently. As a result, the device can provide 40 times wider bandwidth than existing antennas periodically arranged. "We are proposing a new way to connect nanoscale microprocessors to ultra-high-speed optical communications," comments Dr Choi. The research is described in the article “Control of Randomly Scattered Surface Plasmon Polaritons for Multiple-input and Multiple-output Plasmonic Switching Devices, “ published in Nature Communications.

More nano-antennas for higher information transmission bandwidth

The team used surface plasmons to mediate optoelectronic signaling. At the nano-antennas, optical signals are converted to surface plasmons, which then propagate through the metal surface as electric signals. The researchers randomly arranged the nano-antennas, and the surface plasmons generated at each antenna underwent multiple scattering to minimize redundancy between the antennas. In this way, each of the antennas can be used independently, resulting in a substantial increase in the effective number of antennas to more than 40 times. An increase in the number of antennas means an increase in the number of multiple input channels in the MIMO communication, which leads to an increase in the information transmission bandwidth.

Controlling surface plasmon

To exploit the benefit of disordered arrangement of antennas, the team had to resolve an innate problem. Random multiple scattering by disorderly arranged nano-antennas is unpredictable, and cannot be used for information transfer without special measure. The researchers analyzed the patterns of multiple-scattered surface plasmons for various optical inputs and found a particular optical input signal that could send the desired signal to a particular microprocessor. The spatial light modulator was used to generate the identified optical input signal, and the surface plasmon could be controlled freely. "Using this," offers Choi, "we proved that we can transmit signals to six different microprocessors at the same time and proved that optical images are converted into plasmons.”

Labels: optical communications,Wonshik Choi,Center for Molecular Spectroscopy and Dynamics,Plasmonic Switching Devices,surface plasmon

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