The race is on to build the first ‘useful’ quantum computer. Small-scale quantum computers already exist, such as IBM’s Quantum System One and Google’s Sycamore. But these devices have only 10s or 100s of qubits; a ‘useful’ quantum computer requires 1,000s of qubits.

A key goal is to demonstrate ‘absolute quantum advantage’, by proving that quantum computers are faster than the best available classical supercomputers. This is done by performing benchmark tasks, but these tasks are designed only to test the software, they have few real-world applications.

Soon, we’ll have quantum computers larger and better than the current ones, but not yet good enough for the methods from computer science to work. In this regime of a few thousand qubits, all the details of the structure of the noise and of the physical qubit are important. Therefore, we need to bridge methods from computer science with methods from engineering and physics to tailor hardware-specific error mitigation.

The 1kQubit flagship will develop such methods, setting the foundations for the future of quantum computation. It aims to:

• Develop next-generation qubits
• Design practical high-rate error-correction codes and fault-tolerant logic gates
• Build software, including high-threshold, efficient decoders, to perform error correction and logic gates

If successful, the 1kQubit flagship will create the foundations for error-corrected quantum computers and lead to the first demonstrations of scalable error correction.

The 1kQubit flagship launched at the start of 2021, as a spin-off from the Designer Quantum Materials research program.