Planckian develops new superconducting quantum computer architecture to solve critical wiring problem

Planckian’s new superconducting chip architecture drastically reduces cabling complexity, laying the groundwork for quantum computers to fault-tolerant sizes

PISA, ITALY, December 17, 2024 /EINPresswire.com/ -- Planckian, an innovator in quantum technology, today announced the release of a new blueprint for the development a superconducting quantum chip natively designed to address the wiring problem. The new chip architecture employs a cutting-edge control setup that manipulates qubits via a shared control line while at the same time selectively driving them to perform universal quantum computation.

“The Planckian team has invented a powerful new architecture for superconducting quantum computers that represents an important advance towards scalable, fault tolerant computation,” said Seth Lloyd, professor of mechanical engineering and physics at MIT, an independent researcher who first hypothesized this type of architecture as a solution to this pressing scaling issue. “The design can be implemented with current superconducting technology. It is both simple and elegant: it only relies on global controls, and it dramatically reduces the number of external wires needed to perform universal quantum computation. The proposed `conveyor belt' architecture is a significant advance for the entire field of quantum information processing.”

Superconducting circuits are recognized as one of the most promising approaches for the development of large-scale quantum computers. Nevertheless, their use within quantum chip architecture traditionally relies on the individual control of each qubit, which inevitably leads to complex wiring and control systems as the size increases. In the new research, titled “Conveyor-belt superconducting quantum computer,” researchers from the Company introduce a new chip architecture where a subset of qubits is driven by the same control line (thus globally controlled) and in a way that allows performing a complete set of gate operations.

These features build on the core features of a previous design which was released by the Company in June and is described in a paper titled “A globally driven superconducting quantum computing architecture.” In an industry first, this research introduced a way to leverage challenge-to-mitigate interactions between qubits (“ZZ coupling”) to depict a new chip architecture where multiple qubits can be addressed through a single control line. The platform also allowed to perform the key logical operations required for universal computation, namely single-qubit and two-qubit gates.

The latest architecture enables a drastic reduction in the number of physical qubits compared to the previous design while expanding the number of multi-qubit operations that can be performed in single steps, by including a three-qubit gate (“Toffoli gate”).

“This new streamlined layout significantly enhances the advantages of our superconducting architecture, which aims to cut the complexity of wirings and address fundamental challenges hindering scalability that are starting to become critical. Our approach is purpose-built for scalability and it allows not only to reduce the costs associated with control apparatus but also to reduce the thermal noise” said Marco Polini, CSO of Planckian. “We believe that these blueprints coupled with advancements in experimental developments planned in our roadmap open the door to collaborations that enable progress across the quantum computing ecosystem”.

About Planckian
Planckian, launched in 2023 as a joint spin-off from the University of Pisa and Scuola Normale Superiore, is a quantum company based in Italy. It focuses on developing quantum chip architectures that address challenges such as wiring complexity and qubit crosstalk by design. Planckian's innovative approach includes a global control scheme that drastically reduces the number of control lines required, enhancing the scalability and efficiency of quantum processors. Their mission is to push the boundaries of quantum technology, contributing to the development of next-generation quantum computing systems.

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