• While classical computers use information as bits that are either off or on, represented by '0' or '1', quantum systems utilize superposition and entanglement of particles, such as electrons or photons, or other quanta. In superposition, these qubits are at 0 and 1 states simultaneously. When qubits get entangled, a primary feature of quantum mechanics, a change in one of them causes the other to also change.
  

• Harnessing these features will make it possible to use quantum effects to make major advances in computing, sensing and metrology, simulations, cryptography, and telecommunications. Society's benefits from quantum computing ultimately will include ultra-precise sensors for use in medicine, quantum-based communications, and hacking-proof digital data. In the long term, quantum computing has the potential to solve computational problems that would take current supercomputers longer than the age of the universe. These systems will also be able to recognize patterns and train artificial intelligence systems.
  

Europe is well-positioned to take the EU's spin-qubit R&D to the next level, in what is a high-stakes competition among advanced technological countries, said Maud Vinet, CEA-Leti's quantum hardware program manager, who will lead the four-year, €15 million ($17.7 million) project. The QLSI project ramps up a dedicated effort across all leading European groups in the field of spin qubits to develop complete processor systems that eventually will reach the thousands of qubits expected as a first step to show the potential for universal, error-corrected quantum computing.

QLSI will pursue four essential results:

• Fabrication and operation of 16-qubit quantum processors based on industry-compatible semiconductor technology
• Demonstration of high-fidelity (>99 percent) single- and two-qubit gates, read-out and initialization with these devices in a lab environment
• Demonstration of a quantum computer prototype, with online open-access for the community, integrating such a high-quality quantum processor in a semi-industrial environment (up to eight qubits available online), and

• Documentation of the requirements to address important issue of scalability towards large systems >1,000 qubits.
  

The project is a recent addition to the EU's ambitious Quantum Flagship program, a 10-year, €1 billion ($1.18 billion) R&D initiative launched in 2018. It is a coherent set of research and innovation projects selected through a thorough peer-review process. The overall goal is to consolidate and expand European scientific leadership and excellence in quantum computing, to kick-start a competitive European industry in quantum technologies and to make Europe a dynamic and attractive region for innovative research, business and investments in this field.

19 QLSI members for a consortium fully dedicated to quantum hardware solution delivery