Full control of a six-qubit silicon quantum processor

Full control of a six-qubit silicon quantum processor

The six-qubit processor described in this article. Qubits are created by adjusting the voltage on the red, blue, and green wires on the chip. The structures called SD1 and SD2 are very sensitive electric field sensors, which can even detect the charge of a single electron. These sensors, combined with advanced control systems, allowed the researchers to place individual electrons at positions labeled (1) – (6), which were then turned on as qubits. Credit: QuTech

Researchers at QuTech – a collaboration between Delft University of Technology and TNO – have designed a record six silicon-based spin qubits in a fully interoperable array. Importantly, qubits can run at a low error rate that is achieved through a new chip design, automated calibration procedure, and new methods for initializing and reading qubits. These advances will contribute to the development of a scalable silicon-based quantum computer. The results have been published in temper nature today.

Various materials can be used to produce qubits, the quantum counterpart of a part of the classical computer, but no one knows which materials would be best for building a large-scale quantum computer. So far there have been only smaller demonstrations than silicon Quantum chips with high quality qubit operations. Now, researchers from QuTech, led by Professor Levin Vandersiben, have produced a six-qubit chip of silicon that operates at low error rates. This is a major step toward an error-tolerant quantum computer using silicon.

To make qubits, individual electrons are placed in a linear array of six.quantum dotsSpaced 90 nanometers. The array of quantum dots is made in a silicon chip with structures very similar to a transistor — a common component in every computer chip. A quantum-mechanics property called spin is used to identify a qubit with its orientation that defines 0 or 1 logic states: The team used finely tuned microwave radiation, and magnetic fields, and electrical potentials to control the spin and measure individual electrons and make them interact with each other.

“The challenge of quantum computing today has two parts,” first author Mr. Stephan Phillips explained. “Developing qubits of good enough quality, and developing an architecture that allows one to build large systems of qubits. Our work fits both categories. And since the overall goal of building a quantum computer is an enormous effort, I think it is fair to say that we have made a contribution to the direction the correct “.

Electron spin is a sensitive property. Small changes in the electromagnetic environment cause the direction of rotation to fluctuate, and this increases the error rate. The QuTech team built on their previous experience engineering quantum dots with new methods for preparing, controlling, and reading the spin states of electrons. Using this new arrangement of qubits, they can create Logic gates, logic gates And systems of two-electron or three-electron entanglement, as required.

Quantum arrays containing more than 50 qubits have been produced using superconducting qubits. However, it is the global availability of silicon engineering infrastructure that gives silicon quantum devices the promise of an easier transition from research to industry. Silicon brings certain engineering challenges, and until this work from the QuTech team, arrays of up to three qubits can only be designed in silicon without sacrificing quality.

“This paper demonstrates that through precision engineering, it is possible to increase the number of silicon spin qubits while maintaining the same precision of individual qubits. The main building block developed in this research can be used to add more qubits in the following iterations of co-author Dr. Matthews,” said co-author Dr. Matthews. Madzic.

“In this paper, we push the qubit-count envelope in silicon, achieving high initialization resolution, high readout resolution, high single-qubit gate precision, and high sec.qubit “What really stands out is that we demonstrate all of these properties together in one experiment on a record number of qubits,” said Professor Vandersypen.

Semiconductor spinning bits are gaining more credibility as a leading platform for quantum computing

more information:
Lieven Vandersypen et al, Universal control of a six-qubit quantum processor in silicon, temper nature (2022). DOI: 10.1038 / s41586-022-05117-x

the quote: Full control of a six-qubit processor in silicon (2022, September 28) Retrieved on September 29, 2022 from https://phys.org/news/2022-09-full-six-qubit-quantum-processor-silicon. html

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