SubsidieMeestersHigh-Fidelity Quantum Computing with Carbon Nanotubes
C12 Quantum Electronics develops scalable quantum processors using carbon nanotubes for high-fidelity qubits, enabling advanced quantum computing beyond classical supercomputers.
Projectdetails
Introduction
C12 Quantum Electronics builds reliable quantum processors powered by the most elementary material: carbon nanotubes. By utilizing single-electron spins hosted in suspended ultra-clean carbon nanotubes, we achieve the closest realization of an ideal qubit in vacuum.
Technology Integration
We integrate the nanotubes onto semiconductor chips thanks to our proprietary high-throughput technique. Any qubit can be coupled to any other qubit through a custom microwave resonator.
Architecture and Scalability
Thereby, we achieve a scalable and ultra-coherent quantum processor architecture with isolated yet easily addressable qubits. Our carbon nanotube-based technology can scale quantum computing, in the vein of what silicon did for classical computing.
Potential and Applications
Combining the purity of carbon nanotubes and well-established semiconductor manufacturing, our innovation has the potential to process quantum information at large scales with the highest fidelity. Thus, our quantum computers can solve complex problems beyond the reach of any classical supercomputer.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 2.499.000 |
| Totale projectbegroting | € 3.570.000 |
Tijdlijn
| Startdatum | 1-1-2023 |
| Einddatum | 31-12-2024 |
| Subsidiejaar | 2023 |
Partners & Locaties
Projectpartners
- C12 QUANTUM ELECTRONICSpenvoerder
Land(en)
Vergelijkbare projecten binnen EIC Accelerator
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|---|---|---|---|---|
A MILLION QUBIT QUANTUM COMPUTER - HIGHLY SCALABLE SOLID STATE QUANTUM COMPUTING PLATFORM WITH NATIVE OPTICAL NETWORKINGQuantum Transistors aims to develop a highly scalable quantum computing platform with millions of qubits, using efficient cooling methods for broader adoption and reduced costs. | EIC Accelerator | € 2.499.999 | 2024 | Details |
Democratizing quantum computing with 3D scalable and customizable quantum processors:The project aims to revolutionize quantum computing by developing affordable, customizable, and scalable QPUs using innovative technologies, enabling faster access to high-capacity quantum processors. | EIC Accelerator | € 2.499.700 | 2023 | Details |
Scalable Entangled-Photon based Optical Quantum ComputersThe project aims to develop MOSAIQ, a modular photonic quantum computing platform utilizing efficient single photon qubits for scalable quantum computation. | EIC Accelerator | € 2.499.000 | 2023 | Details |
Quantum-enhanced Machine LearningEqual1 aims to finalize a scalable, sustainable quantum processor chip for AI applications, enhancing machine learning capabilities while reducing carbon footprint. | EIC Accelerator | € 2.500.000 | 2022 | Details |
High-Throughput Quantum Chip DiagnosticsWe are developing the Orange Quantum Diagnostics System to automate and expedite the quality assessment of quantum chips, enabling faster transition from research to industry-grade applications. | EIC Accelerator | € 2.499.999 | 2023 | Details |
A MILLION QUBIT QUANTUM COMPUTER - HIGHLY SCALABLE SOLID STATE QUANTUM COMPUTING PLATFORM WITH NATIVE OPTICAL NETWORKING
Quantum Transistors aims to develop a highly scalable quantum computing platform with millions of qubits, using efficient cooling methods for broader adoption and reduced costs.
Democratizing quantum computing with 3D scalable and customizable quantum processors:
The project aims to revolutionize quantum computing by developing affordable, customizable, and scalable QPUs using innovative technologies, enabling faster access to high-capacity quantum processors.
Scalable Entangled-Photon based Optical Quantum Computers
The project aims to develop MOSAIQ, a modular photonic quantum computing platform utilizing efficient single photon qubits for scalable quantum computation.
Quantum-enhanced Machine Learning
Equal1 aims to finalize a scalable, sustainable quantum processor chip for AI applications, enhancing machine learning capabilities while reducing carbon footprint.
High-Throughput Quantum Chip Diagnostics
We are developing the Orange Quantum Diagnostics System to automate and expedite the quality assessment of quantum chips, enabling faster transition from research to industry-grade applications.
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Quantum bits with Kitaev TransmonsThis project aims to develop a novel qubit using a hybrid of superconductors and semiconductors to achieve long coherence times and fault tolerance for scalable quantum computing. | EIC Pathfinder | € 4.749.963 | 2023 | Details |
Scalable Hardware for Large-Scale Quantum ComputingDeveloping a scalable, fault-tolerant quantum computer using advanced cryo-CMOS technology to enhance precision and efficiency in processing complex data across various fields. | EIC Transition | € 2.499.998 | 2023 | Details |
New superconducting quantum-electric device concept utilizing increased anharmonicity, simple structure, and insensitivity to charge and flux noiseConceptQ aims to develop a novel superconducting qubit with high fidelity and power efficiency, enhancing quantum computing and enabling breakthroughs in various scientific applications. | ERC Advanced... | € 2.498.759 | 2022 | Details |
3D Biofabricated high-perfoRmance dna-carbon nanotube dIgital electroniCKS3D-BRICKS aims to revolutionize nanoelectronics by using DNA nanotechnology for scalable, high-performance carbon nanotube-based devices, enhancing efficiency and enabling diverse applications. | EIC Pathfinder | € 3.570.258 | 2023 | Details |
Developing Multi-Core Silicon-Based Quantum ProcessorsThe project aims to develop a scalable FDSOI-based quantum processor demonstrator with a 4X4 multi-core architecture to bridge the gap between semiconductor techniques and quantum computing needs. | EIC Transition | € 2.440.870 | 2024 | Details |
Quantum bits with Kitaev Transmons
This project aims to develop a novel qubit using a hybrid of superconductors and semiconductors to achieve long coherence times and fault tolerance for scalable quantum computing.
Scalable Hardware for Large-Scale Quantum Computing
Developing a scalable, fault-tolerant quantum computer using advanced cryo-CMOS technology to enhance precision and efficiency in processing complex data across various fields.
New superconducting quantum-electric device concept utilizing increased anharmonicity, simple structure, and insensitivity to charge and flux noise
ConceptQ aims to develop a novel superconducting qubit with high fidelity and power efficiency, enhancing quantum computing and enabling breakthroughs in various scientific applications.
3D Biofabricated high-perfoRmance dna-carbon nanotube dIgital electroniCKS
3D-BRICKS aims to revolutionize nanoelectronics by using DNA nanotechnology for scalable, high-performance carbon nanotube-based devices, enhancing efficiency and enabling diverse applications.
Developing Multi-Core Silicon-Based Quantum Processors
The project aims to develop a scalable FDSOI-based quantum processor demonstrator with a 4X4 multi-core architecture to bridge the gap between semiconductor techniques and quantum computing needs.