Future technologies such as virtual reality, augmented reality, holograms, robots and artificial intelligence all rely on having access to affordable high speed, low energy consumption computer hardware. Laser or light based computers hold promise but the holy grail of supercomputer hardware is the Quantum computer.
Qubits, or quantum bits, are the key building blocks that lie at the heart of every quantum computer. In order to perform a computation, signals need to be directed to and from qubits. At the same time, these qubits are extremely sensitive to interference from their environment, and need to be shielded from unwanted signals, in particular from magnetic fields.
Imagine building a processor that has millions of such centimeter-size components. It would be enormous and impractical. Quantum computer size is critical.
It is thus a serious problem that the devices built to shield qubits from unwanted signals, known as nonreciprocal devices, are themselves producing magnetic fields. Moreover, they are several centimeters in size, which is problematic, given that a large number of such elements is required in each quantum processor. Now, scientists at the Institute of Science and Technology Austria (IST Austria), simultaneously with competing groups in Switzerland and the United States, have decreased the size of nonreciprocal devices by two orders of magnitude.
Their device, whose function they compare to that of a traffic roundabout for photons, is only about a tenth of a millimeter in size, and maybe even more importantly,
it is not magnetic. Their study was published in the open access journal Nature Communications.
When researchers want to receive a signal, for instance a microwave photon, from a qubit, but also prevent noise and other spurious signals from traveling back the same way towards the qubit, they use nonreciprocal devices, such as isolators or circulators. These devices control the signal traffic, similar to the way traffic is regulated in everyday life. But in the case of a quantum computer, it is not cars that cause the traffic but photons in transmission lines.
“Imagine a roundabout in which you can only drive counterclockwise”, explains first author Dr. Shabir Barzanjeh, who is a postdoc in Professor Johannes Fink’s group at IST Austria.
At exit number one, at the bottom, there is our qubit. Its faint signal can go to exit number two at the top. But a signal coming in from exit number two cannot travel the same path back to the qubit. It is forced to travel in a counterclockwise manner, and before it reaches exit one, it encounters exit three. There, we block it and keep it from harming the qubit
The ’roundabouts’ the group has designed consist of aluminum circuits on a silicon chip and they are the first to be based on micro-mechanical oscillators: Two small silicon beams oscillate on the chip like the strings of a guitar and interact with the electrical circuit. These devices are tiny in size (only about a tenth of a millimeter in diameter ), one of the major advantages the new component has over its traditional predecessors, which were a few centimeters wide.
Currently, only a few qubits have been used to test the principles of quantum computers, but in the future, thousands or even millions of qubits will be connected together, and many of these qubits will require their own circulator.
Advances for quantum computer size.
“Imagine building a processor that has millions of such centimeter-size components. It would be enormous and impractical,” says Shabir Barzanjeh.
Using our nonmagnetic and very compact on-chip circulators instead makes life a lot easier.
Yet some hurdles need to be overcome before the devices will be used for this specific application. For example, the available signal bandwidth is currently still quite small, and the required drive powers might harm the qubits. However, the researchers are confident that these problems will turn out to be solvable.
About the Research.
Professor Johannes Fink joined IST Austria in the beginning of 2016. He and his group study quantum physics in electrical, mechanical and optical chip-based devices with the main objective of advancing and integrating quantum technology. Earlier this year, he received a prestigious ERC Starting Grant for his project to develop a fiber optic transceiver for superconducting qubits, as well as a research grant from the Swiss NOMIS foundation.
Dr. Shabir Barzanjeh was awarded a Marie Skodowsa-Curie fellowship to work at IST Austria. His main interests are in circuit quantum electrodynamics and optomechanics.
From February 12 to 14, 2018, Johannes Fink und Shabir Barzanjeh will host the international conference „Frontiers of Circuit QED and Optomechanics” (FCQO 2018) in Klosterneuburg with the aim to bring together leading scientists in the field.