World's first photonic router brings quantum computers closer

Scientists have created the world's first photonic router, an advance that brings superfast quantum computers a step closer to reality.
The photonic router - a quantum device based on a single atom that enables routing of single photons by single photons - was developed by the Weizmann Institute of Science in Israel.
At the core of the device is an atom that can switch between two states.
The state is set just by sending a single particle of light - or photon - from the right or the left via an optical fibre. The atom, in response, then reflects or transmits the next incoming photon, accordingly.

For example, in one state, a photon coming from the right continues on its path to the left, whereas a photon coming from the left is reflected backwards, causing the atomic state to flip, researchers said.
In this reversed state, the atom lets photons coming from the left continue in the same direction, while any photon coming from the right is reflected backwards, flipping the atomic state back again.

This atom-based switch is solely operated by single photons - no additional external fields are required.
"In a sense, the device acts as the photonic equivalent to electronic transistors, which switch electric currents in response to other electric currents," said Dr Barak Dayan, head of the Weizmann Institute's Quantum Optics group.

The photons are not only the units comprising the flow of information, but also the ones that control the device.
The main motivation behind the effort to develop quantum computers is the quantum phenomenon of superposition, in which particles can exist in many states at once, potentially being able to process huge amounts of data in parallel.
Yet superposition can only last as long as nothing observes or measures the system otherwise it collapses to a single state.
Therefore, photons are the most promising candidates for communication between quantum systems as they do not interact with each other at all, and interact very weakly with other particles.

"The road to building quantum computers is still very long, but the device we constructed demonstrates a simple and robust system, which should be applicable to any future architecture of such computers," Dayan said.
"In the current demonstration a single atom functions as a transistor - or a two-way switch - for photons, but in our future experiments, we hope to expand the kinds of devices that work solely on photons, for example new kinds of quantum memory or logic gates," he added.