Invisibility cloaking allows new light-detecting device 'see without being seen'

Washington, May 22 (ANI): Using "plasmonic cloaking," engineers at Stanford and the University of Pennsylvania have created an invisible, light-detecting device that can "see without being seen."

It is the first example of what the researchers describe as a new class of devices that controls the flow of light at the nanoscale to produce both optical and electronic functions.

At the heart of the device are silicon nanowires covered by a thin cap of gold. By adjusting the ratio of metal to silicon - a technique the engineers refer to as tuning the geometries - they capitalize on favorable nanoscale physics in which the reflected light from the two materials cancel each other to make the device invisible.

Pengyu Fan, a doctoral candidate in materials science and engineering at Stanford University working in Professor Mark Brongersma's group, is the lead author of the study.

Brongersma, a Keck Faculty Scholar in the School of Engineering, is senior author of the study.

Light detection is well known and relatively simple. Silicon generates electrical current when illuminated and is common in solar panels and light sensors today. The Stanford device, however, is a departure in that for the first time it uses a relatively new concept known as plasmonic cloaking to render the device invisible.

The field of plasmonics studies how light interacts with metal nanostructures and induces tiny oscillating electrical currents along the surfaces of the metal and the semiconductor. These currents, in turn, produce scattered light waves.

By carefully designing their device - by tuning the geometries - the engineers have created a plasmonic cloak in which the scattered light from the metal and semiconductor cancel each other perfectly through a phenomenon known as destructive interference.

The rippling light waves in the metal and semiconductor create a separation of positive and negative charges in the materials - a dipole moment, in technical terms. The key is to create a dipole in the gold that is equal in strength but opposite in sign to the dipole in the silicon. When equally strong positive and negative dipoles meet, they cancel each other and the system becomes invisible.

"We found that a carefully engineered gold shell dramatically alters the optical response of the silicon nanowire. Light absorption in the wire drops slightly - by a factor of just four - but the scattering of light drops by 100 times due to the cloaking effect, becoming invisible," said Fan.

"It seems counterintuitive," said Brongersma, "but you can cover a semiconductor with metal - even one as reflective as gold - and still have the light get through to the silicon. As we show, the metal not only allows the light to reach the silicon where we can detect the current generated, but it makes the wire invisible, too."

The engineers have shown that plasmonic cloaking is effective across much of the visible spectrum of light and that the effect works regardless of the angle of incoming light or the shape and placement of the metal-covered nanowires in the device. They likewise demonstrate that other metals commonly used in computer chips, like aluminum and copper, work just as well as gold.

To produce invisibility, what matters above all is the tuning of metal and semiconductor.

"If the dipoles do not align properly, the cloaking effect is lessened, or even lost. Having the right amount of materials at the nanoscale, therefore, is key to producing the greatest degree of cloaking," said Fan.

In the future, the engineers foresee application for such tunable, metal-semiconductor devices in many relevant areas, including solar cells, sensors, solid-state lighting, chip-scale lasers, and more.

In digital cameras and advanced imaging systems, for instance, plasmonically cloaked pixels might reduce the disruptive cross-talk between neighboring pixels that produces blur. It could therefore lead to sharper, more accurate photos and medical images.

The study was published online May 20th in the journal Nature Photonics. (ANI)