Summary
Spin qubits in germanium have resulted in the most advanced semiconductor quantum processor. Within five years of development, germanium qubits are established as a highly promising candidate for large-scale quantum computing. Germanium is a standard semiconductor manufacturing material and germanium qubits are the only semiconductor qubits that are defined exclusively by transistor-based structures and has enabled to demonstrate a universal quantum gate set [Hen20]. This is highly promising for scalability and adoption by leading semiconductor technology. A revolution in the growth of strained germanium sparked a remarkable development which led to the first germanium quantum dot, germanium qubit, two-qubit logic in germanium, four-qubit logic in a two-dimensional array, and operation of a 16 quantum dot array. This program brings together all the partners that enabled these developments to form a consortium with leading scientists and industry, to fulfil the promise of germanium quantum technology, by scaling the number of qubits, by designing architectures allowing to advance beyond 1000s of qubits, and by experimentally implementing a computational task that can provide a quantum advantage. The key objective of Integrated Germanium Quantum Technology (IGNITE) is thus to demonstrate that germanium defines a compelling platform for quantum computation with excellent qubits operating in a scalable network. We therefore focus on four key components to demonstrate its success:
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| Web resources: | https://cordis.europa.eu/project/id/101069515 |
| Start date: | 01-07-2022 |
| End date: | 30-06-2025 |
| Total budget - Public funding: | 4 996 815,75 Euro - 4 996 815,00 Euro |
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Original description
Spin qubits in germanium have resulted in the most advanced semiconductor quantum processor. Within five years of development, germanium qubits are established as a highly promising candidate for large-scale quantum computing. Germanium is a standard semiconductor manufacturing material and germanium qubits are the only semiconductor qubits that are defined exclusively by transistor-based structures and has enabled to demonstrate a universal quantum gate set [Hen20]. This is highly promising for scalability and adoption by leading semiconductor technology. A revolution in the growth of strained germanium sparked a remarkable development which led to the first germanium quantum dot, germanium qubit, two-qubit logic in germanium, four-qubit logic in a two-dimensional array, and operation of a 16 quantum dot array. This program brings together all the partners that enabled these developments to form a consortium with leading scientists and industry, to fulfil the promise of germanium quantum technology, by scaling the number of qubits, by designing architectures allowing to advance beyond 1000s of qubits, and by experimentally implementing a computational task that can provide a quantum advantage. The key objective of Integrated Germanium Quantum Technology (IGNITE) is thus to demonstrate that germanium defines a compelling platform for quantum computation with excellent qubits operating in a scalable network. We therefore focus on four key components to demonstrate its success:Status
SIGNEDCall topic
HORIZON-CL4-2021-DIGITAL-EMERGING-01-30Update Date
09-02-2023
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Organisations
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| TECHNISCHE UNIVERSITEIT DELFT (Coördinator)
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| Budapest University of Technology and Economics
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| INSTITUTE OF SCIENCE AND TECHNOLOGY AUSTRIA
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| INTERUNIVERSITAIR MICRO-ELECTRONICA CENTRUM VZW
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| KOBENHAVNS UNIVERSITET
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| MULTIVERSE COMPUTING SL
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| Politecnico di Milano
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| QDEVIL APS
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| UNIVERSITAT KONSTANZ