A special case of an entangled state is the Bell state, which is the simplest and maximally entangled quantum states of two qubits. If the two particles are — independently — measured the same way, they will produce identical outcomes even though each outcome is itself random. It’s as though two coins were flipped in different cities, but always gave the same result as each other.

One such application is quantum teleportation, where the concept of entanglement can be used to transfer an unknown quantum state between parties that share entanglement. And if that teleported particle was itself entangled to another particle, we have the process of entanglement swapping. To understand it, we’ll have to introduce Alice, Bob and Christine.

Imagine each of these people has control over quantum particles. Christine and Alice share an entangled pair of particles, and so do Christine and Bob. The goal is to get Bob’s particle entangled with Alice’s particle, but they have no direct link.

Bob and Alice will each begin by preparing known Bell pairs, which are the entangled quantum states of two qubits. Alice will send one prepared qubit to Christine and keep one, and Bob will also send one qubit to Christine and keep one. Christine performs something called a Bell projection between her newly acquired qubits, and error corrections are performed, resulting in the qubit Bob sent to Christine being teleported to Alice, and vice versa. The net effect is that Bob’s and Alice’s qubits are now entangled with each other, thereby creating entanglement over a longer link and setting the stage for a large-scale quantum network.

Entanglement swaps like this will be the foundation of any future quantum repeaters, since they link together nodes that are otherwise unconnected. Think of it like playing the telephone game in a noisy party. A person can’t properly relay information if she doesn’t hear it correctly, and the same can be said of quantum repeaters. As it stands, entanglement swapping seems to be the most effective way to transfer quantum information over long and lossy channels without losing or corrupting the fragile quantum states. Future quantum repeaters will rely on entanglement swapping, and Q-NEXT is working hard to better understand how these repeaters will be built.

What’s the Value?

Quantum computing is an inherently hard-to-understand topic, and as such people often ask what the real-world value of this technology is. To understand why someone might want a quantum repeater, we’ll need to discuss the value of transferring information over a quantum network.

One of the applications of quantum networking is cryptography. Moving data across a network comes with the risk of an attacker either stealing or altering that data, and security measures must be employed.

Quantum key distribution (QKD) is a promising technology that would rely on quantum repeaters. QKD is a secure communication method using the unique properties of quantum physics — in particular, the no-copying dictum — to protect data from attackers. If we want QKD to be efficient and effective, we’ll need to spread the network over large distances. As such, robust quantum repeaters would be used in large-scale QKD deployment.

A second application of a quantum network involves quantum computers. The only way to both securely and remotely program such a processor is via a quantum link. Moreover, a high-speed quantum network can be used to directly connect two or more quantum processes to create one giant distributed quantum processor. For example, two quantum computers acting as one are more powerful than them acting independently. If each quantum processor is a million times more powerful than a classical computer, the entangled contribution of them is a million million times more powerful.

Lastly, quantum networks could enable fantastically sensitive distributed quantum sensors. For instance, Kwiat points out that telescopes and the study of the cosmos will evolve rapidly with the implementation of a quantum network. Right now, we rely on a method that can take an array of physical telescopes and combine their incoming data to simulate one giant telescope, but these methods work only for radio waves, or over short distances. Quantum repeaters could help us link telescopes together more effectively.

“If instead, you could use a quantum network to link two telescopes together, you’d basically be teleporting the signal from one telescope to another,” Kwiat said. ​“If you’ve already got the quantum network up and running effectively, that transfer of quantum information is lossless. In principle, you could have telescopes that were separated by much, much larger distances, achieving a higher resolution.”

Of course, all these developments require a functioning quantum repeater, which we have not built yet. However, Q-NEXT expects to be a leader in the development of these devices. Q-NEXT scientists are pursuing multiple hardware platforms to realize repeaters, including trapped ions, neutral atoms, and superconducting qubits, as well as the means to interconnect between such devices.

Q-NEXT is also helping organize the global effort in this area. For instance, Q-NEXT and the Chicago Quantum Exchange locally co-organized the Third Workshop for Quantum Repeaters and Networks in Chicago. This workshop was meant to bring the quantum research community together to discuss the opportunities and challenges inherent in developing a quantum repeater. This included a tutorial called ​“Quantum Repeater Networks from Scratch” to spread this knowledge to as many people as possible without requiring any prior quantum experience.

Considering that around 100 researchers from 37 institutions and nine total countries attended the workshop, this was clearly a success for Q-NEXT and the entire quantum community. As the technology needed for quantum communication develops, Q-NEXT will continue to do the hard work necessary to bring a quantum repeater into the world.

This work is supported by the U.S. DOE National Quantum Information Science Research Centers as part of the Q-NEXT center.