Electrically switchable qubit can tune between storage and fast calculation modes

- EN - DE
Electrically switchable qubit: a nanowire made of germanium and silicon (blue/gr
Electrically switchable qubit: a nanowire made of germanium and silicon (blue/green) lies on electrodes known as gates (gold). Voltages applied to the gates lead to the formation of individual spin qubits (blue and red arrows) that can be manipulated by microwave signals (blue pulse). In one mode, the qubit is slow and the quantum information is more stable (blue spin). In the other, the qubit can be changed more quickly (red spin). (Image: University of Basel, Department of Physics)

To perform calculations, quantum computers need qubits to act as elementary building blocks that process and store information. Now, physicists have produced a new type of qubit that can be switched from a stable idle mode to a fast calculation mode. The concept would also allow a large number of qubits to be combined into a powerful quantum computer, as researchers from the University of Basel and TU Eindhoven have reported in the journal -Nature Nanotechnology-.

Compared with conventional bits, quantum bits (qubits) are much more fragile and can lose their information content very quickly. The challenge for quantum computing is therefore to keep the sensitive qubits stable over a prolonged period of time, while at the same time finding ways to perform rapid quantum operations. Now, physicists from the University of Basel and TU Eindhoven have developed a switchable qubit that should allow quantum computers to do both.

The new type of qubit has a stable but slow state that is suitable for storing quantum information. However, the researchers were also able to switch the qubit into a much faster but less stable manipulation mode by applying an electrical voltage. In this state, the qubits can be used to process information quickly.

Selective coupling of individual spins

In their experiment, the researchers created the qubits in the form of “hole spins’. These are formed when an electron is deliberately removed from a semiconductor, and the resulting hole has a spin that can adopt two states, up and down - analogous to the values 0 and 1 in classical bits. In the new type of qubit, these spins can be selectively coupled - via a photon, for example - to other spins by tuning their resonant frequencies.

This capability is vital, since the construction of a powerful quantum computer requires the ability to selectively control and interconnect many individual qubits. Scalability is particularly necessary to reduce the error rate in quantum calculations.

Ultrafast spin manipulation

The researchers were also able to use the electrical switch to manipulate the spin qubits at record speed. “The spin can be coherently flipped from up to down in as little as a nanosecond,’ says project leader Professor Dominik Zumbühl from the Department of Physics at the University of Basel. “That would allow up to a billion switches per second. Spin qubit technology is therefore already approaching the clock speeds of today’s conventional computers.’

For their experiments, the researchers used a semiconductor nanowire made of silicon and germanium. Produced at TU Eindhoven, the wire has a tiny diameter of about 20 nanometers. As the qubit is therefore also extremely small, it should in principle be possible to incorporate millions or even billions of these qubits onto a chip.

The work was carried out as part of the National Centre of Competence in Research (NCCR) SPIN, which was launched in 2020. The NCCR SPIN is working on scalable spin qubits in semiconductor silicon and germanium nanostructures, and developing small and fast qubits for a universal quantum computer. The SPIN network encompasses not only EPFL and ETH Zurich, but also the industry partner IBM Research - and brings together research groups in the areas of experimental and theoretical physics, materials science, engineering sciences and computer science.

Original publication

Florian N. M. Froning, Leon C. Camenzind, Orson A. H. van der Molen, Ang Li, Erik P. A. M. Bakkers, Dominik M. Zumbühl, and Floris R. Braakman
Ultrafast hole spin qubit with gate-tunable spin-orbit switch functionality
Nature Nanotechnology (2021); doi: 10.1038/s41565-020-00828-6