Quantum computers promise to enable a computing power far beyond the capabilities of modern-day classical and super computers. This new approach to computing harnesses quantum-mechanical properties, like superposition and entanglement, to achieve unprecedented performance and is expected to revolutionise research in, among others, chemistry, medicine and materials research. However, a quantum computer capable of solving useful problems will require millions of high-quality quantum bits (qubits) working together. Currently, there are several qubit hardware platforms that are being studied and commercialised. This commercialisation mainly focuses on superconducting transmon qubits, photonic qubits and qubits made with trapped ions. Although these platforms enabled the first breakthroughs in quantum computing research and are developing steadily, the large size of the qubit system may hamper their scaling towards the millions of qubits required for useful quantum computations.
This scaling problem may well be overcome by moving to a semiconductor qubit platform. To date, semiconductor manufacturing technology is the only technology supporting the integration of billions of components onto a single chip. These semiconductor elements are fabricated with an immense precision and consistency, with over 1 trillion components being shipped every year. The integration of billions of transistors on a single chip underpins our current information age. What materials do we need to integrate excellent qubits at large scale for the quantum information age of tomorrow? A semiconductor qubit system may well be the answer and the only feasible way to scale quantum technology to the requisite millions of qubits, while meeting the requirements on feature size and component reproducibility to produce high-yield, high-quality quantum chips. This system provides a clear advantage over current state-of-the-art quantum technologies, where fault-tolerant processors are predicted to take enormous sizes, resulting in a wide range of additional challenges. Moreover, semiconductor qubits can have extremely long coherence times, can be operated with high-fidelity, and can be integrated with classical control electronics. These proof-of-principle operations, together with the decades-long growing investments and resulting technological advances in the semiconductor industry, position semiconductor quantum technology as the designated platform for the fabrication of millions of qubits.
Going beyond few-qubit experiments, in this project we aim to develop a robust framework enabling semiconductor quantum technology to provide a practical quantum advantage. The main objective of Groove is to reproducibly fabricate, test and launch a quantum chip containing 16 high-quality germanium spin qubits. This quantum computer prototype will leverage the small footprint and rapid development of spin qubits in gate-defined quantum dots in combination with the unique properties of the germanium host material. As our research to date has demonstrated promising results for high-quality qubits in germanium, we aim to explore the robustness and scalability that are essential commercialisation. Scientific research often focuses on hero devices and a one-off demonstration of high-fidelity or multi-qubit milestones, with the different state-of-the-art performance metrics (qubit initialization, operation, entanglement, readout) being achieved in a wide variety of devices. However, for commercialisation it is absolutely essential that these quality requirements are consistently achieved in a single device. We strive to make the platform robust by developing high-yield and highly reproducible sample fabrication where all qubits conform to a high minimal fidelity.