TUM Team Implements Secure Communications Between Quantum Computers



An international team headed by physicists from the Technical University of Munich (TUM) has, for the first time ever, experimentally implemented secure quantum communication in the microwave band in a local quantum network. The new architecture represents a crucial step on the road to distributed quantum computing.


Press release from TUM
October 25th 2019 | 934 readers

Quantum circuit, developed at the Walther-Meissner-Institut (WMI), which can be used to produce restricted microwave states. Image courtesy of TUM.
As of yet, there are no universal quantum computers in the world. But for the first time, an international team led by TUM physicists Rudolf Gross, Frank Deppe and Kirill Fedorov has successfully implemented secure quantum communication in a local network – via a 35-centimeter superconducting cable.”We have thus laid the foundation for implementing quantum communication systems in the very important microwave range,” says Rudolf Gross, professor of technical physics at the Technical University of Munich and director of the Walther Meißner Institute (WMI), where the experiments took place. “This is a milestone. This puts the quantum internet, based on superconducting circuits and microwave communications, within arm’s reach.”

Years of pioneering work

Researchers at WMI have been pioneering the propagation of quantum microwaves for more than a decade. First, they had to prove that microwave radiation even has quantum mechanical properties. Unlike with visible light, this was extremely challenging from a technical point of view, due to the low energy of the microwave photons.

To eliminate interferences, the experiments were done at temperatures near absolute zero. Using special cooling devices, the physicists ultimately succeeded in demonstrating the principle of entanglement in the microwave range, an important prerequisite for reliable quantum communication.

Wiretapping-proof protocol using entanglement

The physicists’ current work brings them one step closer to the actual application: “Quantum Remote State Preparation,” as they call their communication protocol. A quantum state can be set at a remote location without sending anything directly.

The concept can be visualized as follows: Two people, let’s call them Alice and Bob, are in two different places. While a bit is the smallest piece of information in classical informatics, in quantum communication it is a quantum state.

Now, if Alice wants to send Bob a piece of information, both are given part of an entangled quantum mechanical state. Alice then does a measurement on her part of the state and transmits the result to Bob via classical means. Bob, in turn, performs a result-dependent operation on his part of the entangled state, thereby obtaining the quantum state that Alice wants to communicate to him.

The classically transmitted measurement result is of no use to any third party since they will not have the entangled state. This makes communications via this protocol absolutely immune to wiretapping.

Information transmission using squeezed waves

The researchers use a so-called squeezed microwave state as the quantum state. This is a special manifestation of an electromagnetic wave that can only be explained with quantum mechanics.

Here, a wave’s vacuum fluctuations are suppressed in one plane and amplified in the plane perpendicular to the first. Two such squeezed states can be used to produce an entangled state. The physicists developed this technique and other important details, such as superconducting quantum circuits, at the Walther Meißner Institute in Garching.

Seven-meter, cooled quantum cable

The new concept could trigger a revolutionary development. “The experimental implementation of secure quantum communication in the microwave domain is an important step towards distributed quantum computing,” says Frank Deppe, WMI coordinator of the European flagship project Quantum Microwave Communication and Sensing (QMiCS).

The TUM physicists also believe that significantly longer distances are possible between quantum computers. Here, one challenge will be to develop and measure several meters of cooled quantum cables. “In the context of QMiCS, we are already working on extending the distance to seven meters,” says Gross. “This puts networking of superconducting quantum computers within reach.”

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