Engineers at EPFL have developed a way to study several qubits – the smallest units of quantum information – in the same time. Their technique best paves the way for an entirely new technology of much more efficient quantum computer systems.
“IBM and Google currently have the most powerful quantum computing systems in the world,” said Professor Edoardo Charbon, head of the Advanced Quantum Structures Laboratory (AQUA Lab) in EPFL’s Faculty of Engineering. “IBM simply announced a 127 qubit machine, while Google’s is 53 qubits.” However, the scope of fabricating quantum computer systems was even banned early on, hence a higher degree of certainty about the diversity of qubits. However, a workforce of engineers led by Charbon, in collaboration with researchers in the United Kingdom, has simply developed a promising technique to break down this technological barrier. Their strategy could be to learn qubits more efficiently, which means more qubits could be packed into quantum processors. Their findings appear to be in Nature Electronics.
Biochemistry and cryptography
Quantum computer systems don’t work like the ones we used to. As an alternative to getting a separate processor and memory chip, the two are immediately mixed into a single unit commonly known as a qubit. These computer systems use quantum properties equivalent to superposition and entanglement to perform difficult calculations that cannot be done by conventional computer systems within a reasonable time frame. Potential uses for quantum computer systems include biochemistry, cryptography, etc. The machines used by analytical teams today have about a dozen qubits.
“Our problem now is to connect additional qubits to quantum processors – we are talking a lot, even 1000 – to increase the processing power of the computing system,” Charbon said. ,” said Charbon.
The variety of qubit types is currently limited by the fact that there is no know-how but it is possible to learn all qubits quickly. “Additionally complicating matters, qubits operate at near temperatures not absolute, or –273.15oC,” said Charbon. “That makes studying and controlling them even more durable. What engineers usually do is use machines at room temperature and manage each qubit individually.”
“It was a real breakthrough”
Andrea Ruffino, a doctoral student in Charbon’s lab, has developed a way that allows 9 qubits to be learned simultaneously and successfully. Furthermore, his strategy can be extended equivalently to larger qubit matrices. “Our technique is based on the use of time and frequency domains,” he explains. “The basic idea is to cut down on the variety of connections by having three qubits work with a single link.”
EPFL doesn’t have a quantum computer, but that didn’t stop at Ruffino. He discovered a strategy to simulate qubits and run experiments under almost identical circumstances as in a quantum computer. “I integrated quantum dots, which are nanometer-sized semiconductor particles, right into a transistor. That gave me something that works exactly like a qubit,” Ruffino said.
He is a principal PhD student in AQUA Labs to look at this issue for his thesis. “Andrea confirmed that his technique works with built-in circuits on conventional computer chips and at temperatures close to qubits,” says Charbon. “It’s a real breakthrough that makes it possible to make techniques for huge qubit matrices pre-integrated with the necessary electronics. Two types of know-how can work simply, successfully and in a reproducible method. “
Reference: “A cryo-CMOS chip that integrates silicon quantum dots and composite distributed reading electronics” by Andrea Ruffino, Tsung-Yeh Yang, John Michniewicz, Yatao Peng, Edoardo Charbon and Miguel Fernando Gonzalez-Zalba, 27 December 2021, Nature Electronics.
DOI: 10.1038 / s41928-021-00687-6
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