Physicists design quantum switches which can be activated by single photons

April 18, 2014, Harvard University
Professor of Physics Mikhail Lukin (from left) led a team consisting of postdoctoral fellow Tobias Tiecke and graduate student Jeff Thompson that has created quantum switches that could one day be networked via fiber-optic cables to form the backbone of a “quantum Internet” that allows for perfectly secure communications, said Lukin. Credit: Kris Snibbe/Harvard Staff Photographer

Harvard researchers have succeeded in creating quantum switches that can be turned on and off using a single photon, a technological achievement that could pave the way for the creation of highly secure quantum networks.

Built from single atoms, the first-of-their-kind switches could one day be networked via fiber optic cables to form the backbone of a "quantum Internet" that allows for perfectly secure communications, said Professor of Physics Mikhail Lukin, who led a team consisting of graduate student Jeff Thompson and post-doctoral fellow Tobias Tiecke to construct the new system. Their research is detailed in a recently published paper in Nature.

"From a technical standpoint, it's a remarkable accomplishment," Lukin said of the new advance. "Conceptually, the idea is very simple – push the conventional light switch to its ultimate limit. What we've done here is to use a single atom as a switch that, depending on its state, can open or close the flow of photons…and it can be turned "on" and "off" using a single photon."

Though the switches could be used to build a quantum computer, Lukin said it's unlikely the technology will show up in the average desktop computer.

Where they will be used, he said, is in creating fiber optical networks that use , a method for encrypting communications using the laws of quantum mechanics to allow for perfectly secure communication. Such systems make it impossible to intercept and read messages sent over the network, because the very act of measuring a quantum object changes it, leaving behind telltale signs of the spying.

"It's unlikely everyone would need this type of technology," he said. "But there are some realistic applications that could someday have transformative impact on our society. At present, we are limited to using quantum cryptography over relatively short distances – tens of kilometers. Based on the new advance, we may eventually be able to extend the range of quantum cryptography to thousands of kilometers."

Importantly, Tiecke said, their system is highly scalable – and could one day allow for the fabrication of thousands of such switches in a single device.

"What we've really done is taken ideas that people have been exploring, and still are exploring, in macroscopic systems where the light bounces back and forth on two centimeter-sized mirrors to interact with an atom – we've taken that and shrunk it down," said Thompson. "For two decades, researchers have been working on coupling two or three of these macroscopic systems and create a simple network, but it's very easy for us to create three or four, or 10,000 of these optical circuits. What the present paper shows is, at least technologically, the way forward."

That is one way, Lukin believes, for quantum systems to make the same transition conventional computers made decades ago – from vacuum tubes to integrated circuits.

"Conventional computers were initially built using vacuum tubes, and people eventually developed integrated circuits used in modern computers," he said. "Where quantum systems stand today, the best systems are still analogous to vacuum tubes – they typically use vacuum chambers to isolate and hold single atoms using electromagnetic fields.

"But it's very clear, if we want to scale these systems up, we have to think about using integrated circuits," he continued. "What Jeff and Tobias have done is create a hybrid system. We take atoms in vacuum chambers and combine them with integrated circuits."

Though fabricated in a similar way traditional computer chips are made, the built by Thompson and Tiecke don't run on electricity, but on light.

The chips use nano-photonic technology – essentially the ability to create "wiring" that can channel and control the pathway of light – to build optical circuits which can then be connected to fiber optic cables.

After placing the in a vacuum chamber, researchers used "optical tweezers" – precisely focused lasers – to capture a single atom and cool it to a fraction above absolute zero temperature. They then move the atom to within a few hundred nanometers of the chip.

Simply bringing the two parts together, however, isn't enough.

To create quantum switches that may one day be at the heart of , they bombard the atom with microwaves and lasers, causing it to enter a quantum superposition state – meaning it can occupy multiple quantum states, corresponding to "on" and "off" states of the switch, at once.

"For this to work, the atom switch must be prepared in this special superposition state ," Lukin explained. "This superposition state is extremely fragile – so fragile that when a single photon hits it, it actually changes its phase. That change of phase is what allows it to act like a valve, and be turned on or off."

While it's unlikely the switches will become standard equipment for personal computers, Lukin said they could appear in prototype quantum networks in as little as a decade.

"There are other systems that are more sophisticated in terms of building a quantum computer," Thompson said. "But the key advantage to what's demonstrated in this paper is the single atom switch is very tightly coupled to light, and specifically to light in optical fibers."

Explore further: New 'switch' could power quantum computing

More information:

Related Stories

New 'switch' could power quantum computing

April 9, 2014

Using a laser to place individual rubidium atoms near the surface of a lattice of light, scientists at MIT and Harvard University have developed a new method for connecting particles—one that could help in the development ...

A single-atom light switch

November 5, 2013

With just a single atom, light can be switched between two fibre optic cables at the Vienna University of Technology. Such a switch enables quantum phenomena to be used for information and communication technology.

A quantum logic gate between light and matter

April 10, 2014

Scientists at Max Planck Institute of Quantum Optics, Garching, Germany, successfully process quantum information with a system comprising an optical photon and a trapped atom.

Into the quantum internet at the speed of light

February 4, 2013

Not only do optical fibers transmit information every day around the world at the speed of light, but they can also be harnessed for the transport of quantum information. In the current issue of Nature Photonics, a research ...

Progress in the fight against quantum dissipation

April 16, 2014

( —Scientists at Yale have confirmed a 50-year-old, previously untested theoretical prediction in physics and improved the energy storage time of a quantum switch by several orders of magnitude. They report their ...

Recommended for you

CMS gets first result using largest-ever LHC data sample

February 15, 2019

Just under three months after the final proton–proton collisions from the Large Hadron Collider (LHC)'s second run (Run 2), the CMS collaboration has submitted its first paper based on the full LHC dataset collected in ...

Gravitational waves will settle cosmic conundrum

February 14, 2019

Measurements of gravitational waves from approximately 50 binary neutron stars over the next decade will definitively resolve an intense debate about how quickly our universe is expanding, according to findings from an international ...


Please sign in to add a comment. Registration is free, and takes less than a minute. Read more

Click here to reset your password.
Sign in to get notified via email when new comments are made.