Category: Research

Electrically switchable qubit can tune between storage and fast calculation modes

IMAGE: 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… view more 
Credit: 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.
###

Disclaimer: AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert system.

Finicky Things! University of Cambridge has Contrieved a Method to Calm the Qubits

Hidden symmetry could be key to more robust quantum systems, researchers find Researchers have found a way to protect highly fragile quantum systems from noise, which could aid in the design and development of new quantum devices, such as ultra-powerful quantum computers. Until we can find a way to make quantum systems more robust, their […]

“The Curious Observer’s Guide to Quantum Mechanics”, Part 1?

“The Curious Observer’s Guide to Quantum Mechanics”, Part 1? Practical perspective in this first part of a seven part “mathless” series. Some humor and clever analogies get the knowledge across of the complex world of quantum mechanics. Recommend reading from ars TECHNICA, the source. Link is below. Because Quantum is Coming. Qubit. A “no math” […]

Aalto University Researchers Taming Entanglement

Entangling electrons with heat Quantum entanglement is key for next-generation computing and communications technology, Aalto researchers can now produce it using temperature differences   IMAGE: FALSE-COLOUR ELECTRON MICROSCOPE IMAGE OF THE SAMPLE, THE GREEN LAYERS ARE GRAPHENE ON TOP OF THE GREY SUPERCONDUCTOR. THE BLUE METAL ELECTRODES ARE USED TO EXTRACT THE ENTANGLED ELECTRONS… CREDIT: AALTO […]

Quantum Computer Design may be Served Well by Tokyo Institute of Technology Superconductor Study

Quantum Mysteries: Probing an Unusual State in the Superconductor-Insulator Transition Scientists at Tokyo Institute of Technology approach the two decade-old mystery of why an anomalous metallic state appears in the superconductor-insulator transition in 2D superconductors. Through experimental measurements of a thermoelectric effect, they found that the “quantum liquid state” of quantum vortices causes the anomalous […]

Quantum Monte Carlo Approach Dubbed Having Unprecedented Accuracy at Acceptable Computing Cost

Artificial Intelligence Solves Schrödinger’s Equation Scientists at Freie Universität Berlin develop a deep learning method to solve a fundamental problem in quantum chemistry A team of scientists at Freie Universität Berlin has developed an artificial intelligence (AI) method for calculating the ground state of the Schrödinger equation in quantum chemistry. The goal of quantum chemistry […]

The Good of 2020, Quantumly Speaking, and on to 2021

Interesting perspectives from author John Russell.  Recommend reading from the source, below.  Because Quantum is Coming.  Qubit Farewell 2020: Bleak, Yes. But a Lot of Good Happened Too Read More… +  It’s tempting to omit quantum computing this year. Too much happened to summarize easily and the overall feel is of steady carry-on progress from 2019. […]

University of Copenhagen Claims Quantum Advantage in ‘Major Breakthrough’

Major breakthrough: Copenhagen researchers can now achieve ‘quantum advantage’ University of Copenhagen researchers have advanced their quantum technology to such a degree that classical computing technology can no longer keep up. They have developed a chip that, with financial backing, could be scaled up and used to build the quantum simulator of the future. Their […]

Errors, Errors, and More Errors, but Here’s What Could Happen if They Were Corrected…

Good piece for the layperson. Author Stephen Shankland captures the essence of the error-correction and error-mitigation issue keeping quantum computing from arriving. Recommend reading from the source, below. Because Quantum is Coming. Qubit Quantum computer makers like their odds for big progress Key points… +  At the Q2B conference this month, quantum computer makers Google, […]