University of Copenhagen: Internet Speeds Could Achieve Quantum Levels with Light Stored as Sound
Just beneath Niels Bohr’s old office is a basement where scattered tables are covered with small mirrors, lasers and an agglomeration of all types of devices connected by webs of wires and heaps of tape. It looks like a child’s project gone too far, one that their parents have tried in vain to get them to clean up.
While it is difficult for the untrained eye to discern that these tables are actually the home to an array of world-leading research projects, the important stuff is happening within worlds so small that not even Newton’s laws apply. This is where Niels Bohr’s quantum physical heirs are developing the most cutting-edge of quantum technologies.
One of these projects stands out – for physicists at least – by the fact that a gizmo visible to the naked eye is able to achieve quantum states. The quantum drum is a small membrane made of a ceramic, glass-like material with holes scattered in a neat pattern along its edges.
When the drum is beaten with the light of a laser, it begins vibrating, and does so, so quickly and undisturbed, that quantum mechanics come into play. This property has long since caused a stir by opening up a number of quantum technological possibilities.
Now, a collaboration across various quantum areas at the Institute has demonstrated that the drum can also play a key role for the future’s network of quantum computers. Like modern alchemists, researchers have created a new form of “quantum memory” by converting light signals into sonic vibrations.
Facts: How it works
In a just-published research article, the researchers have proven that quantum data from a quantum computer emitted as light signals – e.g., through the type of fiber-optic cable already used for high-speed internet connections – can be stored as vibrations in the drum and then forwarded.
Previous experiments demonstrated to researchers that the membrane can remain in an otherwise fragile quantum state. And on this basis, they believe that the drum should be able to receive and transmit quantum data without it “decohering”, i.e., losing its quantum state when the quantum computers are ready.
“This opens up great perspectives for the day when quantum computers can really do what we expect them to. Quantum memory is likely to be fundamental for sending quantum information over distances. So, what we’ve developed is a crucial piece in the very foundation for an internet of the future with quantum speed and quantum security,” says postdoc Mads Bjerregaard Kristensen of the Niels Bohr Institute, lead author of the new research article.
Ultra-fast, ultra-secure
When transferring information between two quantum computers over a distance – or among many in a quantum internet – the signal will quickly be drowned out by noise. The amount of noise in a fiber-optic cable increases exponentially the longer the cable is. Eventually, data can no longer be decoded.
The classical Internet and other major computer networks solve this noise problem by amplifying signals in small stations along transmission routes. But for quantum computers to apply an analogous method, they must first translate the data into ordinary binary number systems, such as those used by an ordinary computer.
This won’t do. Doing so would slow the network and make it vulnerable to cyber-attacks, as the odds of classical data protection being effective in a quantum computer future are very bad.
“Instead, we hope that the quantum drum will be able to assume this task. It has shown great promise as it is incredibly well-suited for receiving and resending signals from a quantum computer. So, the goal is to extend the connection between quantum computers through stations where quantum drums receive and retransmit signals, and in so doing, avoid noise while keeping data in a quantum state,” says Mads Bjerregaard Kristensen. He adds:
“In doing so, the speeds and advantages of quantum computers, e.g., in relation to certain complex calculations, will extend across networks and the Internet, as they will be achieved by exploiting properties like superposition and entanglement that are unique to quantum states,” he says.
If successful, the stations will also be able to extend quantum-secured connections, whose quantum codes could also be lengthened by the drum. These secure signals could be sent over various distances, whether around a quantum network or across the Atlantic, in the quantum internet of the future.