Light-Bending Microchip Could Fire Up Quantum Computers by Charles Q. Choi, Live Science Contributor | November 24, 2015 10:34am ET
In a new study, researchers were able to bend and "squeeze" light. This light-warping technology could drive the development of light-based microchips for quantum computers. Credit: Peter Allen, Harvard SEAS |
Light travels at the speed of about 670 million miles per hour (1.08 billion km/h) in a vacuum, and is theoretically the fastest possible speed at which matter or energy can travel. Exceeding this speed limit should lead to impossible results such as time travel, according to Einstein's theory of relativity.
However, in a way, researchers have overcome this barrier for decades. [Warped Physics: 10 Effects of Faster-Than-Light Travel].
To understand this feat, imagine a pulse of light as a packet of waves all blended together. The energy of this packet rises and falls across space, cresting somewhere in the middle.
If a pulse of light encounters a material that absorbs, bends or scatters light, the waves making up this packet can interfere with each other, driving its crest forward. This can make the speed at the packet's crest — known as the phase velocity of the pulse — faster than light.
When what are known as zero-index materials enter the mix, light no longer behaves as a set of moving waves zipping through space as a series of crests and troughs. Instead, in zero-index materials, light behaves as either all crests or all troughs, stretched out to infinite wavelengths and traveling at infinite speeds.
All these effects do not make the energy in a group pulse travel faster than light, however, so thetheory of relativity remains unbroken, the researchers said. These altered pulses also get more distorted the faster they go, so it is theoretically impossible to send useful information at faster-than-light speeds.
Still zero-index materials could have exciting applications when it comes to controlling light, the scientists said. For instance, just as electronic devices steer electrons around in circuits, photonic devices manipulate light.
The electrons in electronic components are generally limited to trickling along at only a fraction of the speed of light, because electrons encounter resistance in metal wires, which also results in wasted energy that fizzles away as heat. Photonic devices would not only operate much faster, but they would also be cooler, which means more devices could be packed together in smaller, more powerful computers.
Now, scientists have for the first time woven a zero-index material onto a microchip.
The researchers designed a new metamaterial — an artificial material whose structure is engineered to interact with andmanipulate light in novel ways. The metamaterial consists of arrays of silicon pillars embedded in a soft plastic and clad in reflective gold film.
"Our new metamaterial allows you to bend and squeeze light more or less instantly, to help make light go around very tight turns without losing signals, helping enable photonic circuits," study co-author Eric Mazur, an applied physicist at Harvard University, told Live Science.
Zero-index materials can also help connect photonic microchips to other kinds of devices, such as fiber-optic networks, the researchers said.
"To get light from an ordinary optical fiber onto a microchip, you need to slowly move it from regular scales to microscales," Mazur said. "Zero-index materials allow you to squeeze light instantly from regular scales to microscales."
Zero-index materials that can fit on a chip might also help advance quantum computers, which can theoretically carry out more calculations in an instant than there are atoms in the universe. Quantum computers rely on quantum entanglement, in which two or more particles behave as if they are linked, regardless of distance. By stretching wavelengths of light to infinite lengths, zero-index materials could enable even distant particles to become entangled, said study co-author Philip Munoz, a graduate student in the Department of Engineering and Applied Sciences at Harvard University.
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