SubsidieMeestersOptical Entanglement of Nuclear Spins in Silicon
OpENSpinS aims to enhance silicon-based quantum information processing by using erbium nuclear spins as qubits, enabling long-distance entanglement and scalable quantum networks through advanced photonic integration.
Projectdetails
Introduction
A major breakthrough in quantum information processing is expected once “qubits”, carriers of quantum information, can be reliably integrated and controlled in silicon – the basis of today’s advanced classical information technology.
Background
Previous qubit realizations used the electronic spin of quantum dots or dopants, i.e., atoms of a different species replacing silicon in the lattice. However, this approach has only allowed for the entanglement of qubits in immediate proximity, which has hindered increasing the size of silicon-based quantum information processing systems.
Objectives
In OpENSpinS, these limitations will be overcome by using the nuclear spins of erbium dopants as qubits. These are initialized, read-out, and controllably entangled using photons in the minimal-loss band of existing fiber-optical infrastructure.
To demonstrate the unique potential of this approach, the specific objectives of the proposal are:
- The fabrication of nanophotonic resonators with unprecedented Purcell enhancement to enable coherent spin-photon coupling.
- The direct optical addressing and control of nuclear spin qubits with long coherence.
- The implementation of optically-controlled two-qubit quantum gates and entanglement, both within a node and over distance.
Advantages
The proposed system combines the advantages of two leading platforms for quantum information processing:
- The bandwidth and long-distance connectivity of photons at telecommunications wavelength.
- The robust control and hour-long qubit storage achievable with nuclear spins in silicon.
Conclusion
As the proposed chip-integrated resonators can be manufactured using established processes of the semiconductor industry, the novel hardware platform implemented in OpENSpinS offers unique prospects for future up-scaling of quantum information processing systems and quantum networks.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 1.984.375 |
| Totale projectbegroting | € 1.984.375 |
Tijdlijn
| Startdatum | 1-4-2025 |
| Einddatum | 31-3-2030 |
| Subsidiejaar | 2025 |
Partners & Locaties
Projectpartners
- TECHNISCHE UNIVERSITAET MUENCHENpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
| Project | Regeling | Bedrag | Jaar | Actie |
|---|---|---|---|---|
Spins Interfaced with Light for Quantum Silicon technologiesThe SILEQS project aims to demonstrate indistinguishable single-photon emission and spin control from silicon defects to enable scalable quantum communication technologies. | ERC Starting... | € 1.500.000 | 2022 | Details |
Atomic scale coherent manipulation of the electron spin in semiconductorsOneSPIN aims to coherently probe and engineer single electronic spins in 2D semiconductors using advanced scanning tunneling microscopy to enhance spin coherence for quantum information applications. | ERC Starting... | € 1.913.122 | 2024 | Details |
Quantum Metamaterials with integrated atomic-like arrays for quantum information processingThis project aims to create quantum metamaterials from quantum-emitter arrays to enhance atom-photon entanglement for scalable quantum information processing and one-way quantum computation. | ERC Starting... | € 2.374.938 | 2024 | Details |
Lithium Niobate Quantum systemsThis project aims to develop integrated Lithium Niobate Quantum systems (LiNQs) to create a comprehensive platform for scalable quantum photonic circuits, enhancing Europe's quantum technology capabilities. | ERC Starting... | € 2.499.381 | 2022 | Details |
Silicon opto-electro-mechanics for bridging the gap between photonics and microwavesThe SPRING project aims to achieve efficient microwave-optical conversion and quantum state transfer using a novel optomechanical coupling approach in silicon chips for advanced communication and computing applications. | ERC Consolid... | € 2.491.486 | 2024 | Details |
Spins Interfaced with Light for Quantum Silicon technologies
The SILEQS project aims to demonstrate indistinguishable single-photon emission and spin control from silicon defects to enable scalable quantum communication technologies.
Atomic scale coherent manipulation of the electron spin in semiconductors
OneSPIN aims to coherently probe and engineer single electronic spins in 2D semiconductors using advanced scanning tunneling microscopy to enhance spin coherence for quantum information applications.
Quantum Metamaterials with integrated atomic-like arrays for quantum information processing
This project aims to create quantum metamaterials from quantum-emitter arrays to enhance atom-photon entanglement for scalable quantum information processing and one-way quantum computation.
Lithium Niobate Quantum systems
This project aims to develop integrated Lithium Niobate Quantum systems (LiNQs) to create a comprehensive platform for scalable quantum photonic circuits, enhancing Europe's quantum technology capabilities.
Silicon opto-electro-mechanics for bridging the gap between photonics and microwaves
The SPRING project aims to achieve efficient microwave-optical conversion and quantum state transfer using a novel optomechanical coupling approach in silicon chips for advanced communication and computing applications.
Vergelijkbare projecten uit andere regelingen
| Project | Regeling | Bedrag | Jaar | Actie |
|---|---|---|---|---|
ENABLING NEW QUANTUM FRONTIERS WITH SPIN ACOUSTICS IN SILICONThis project aims to develop a scalable silicon-based quantum information platform by enhancing qubit control, readout, and coupling mechanisms, fostering collaboration across Europe for advanced quantum computing. | EIC Pathfinder | € 3.235.322 | 2025 | Details |
Quantum technology with a spin-photon architecture for thousand-qubit chipsets at telecom wavelengthsQuSPARC aims to develop wafer-scale processes for thousands of high-quality qubit sites in silicon carbide, advancing scalable quantum information devices for million-qubit systems. | EIC Pathfinder | € 2.992.374 | 2025 | Details |
SpIn-orbitronic QuAntum bits in Reconfigurable 2D-OxidesThis project aims to develop a scalable quantum computation platform using spin-orbitronics qubits in 2D oxide materials to enhance coherence and control over individual electron spins. | EIC Pathfinder | € 3.717.545 | 2023 | Details |
Quantum Optical Networks based on Exciton-polaritonsQ-ONE aims to develop a novel quantum neural network in integrated photonic devices for generating and characterizing quantum states, advancing quantum technology through a reconfigurable platform. | EIC Pathfinder | € 3.980.960 | 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 |
ENABLING NEW QUANTUM FRONTIERS WITH SPIN ACOUSTICS IN SILICON
This project aims to develop a scalable silicon-based quantum information platform by enhancing qubit control, readout, and coupling mechanisms, fostering collaboration across Europe for advanced quantum computing.
Quantum technology with a spin-photon architecture for thousand-qubit chipsets at telecom wavelengths
QuSPARC aims to develop wafer-scale processes for thousands of high-quality qubit sites in silicon carbide, advancing scalable quantum information devices for million-qubit systems.
SpIn-orbitronic QuAntum bits in Reconfigurable 2D-Oxides
This project aims to develop a scalable quantum computation platform using spin-orbitronics qubits in 2D oxide materials to enhance coherence and control over individual electron spins.
Quantum Optical Networks based on Exciton-polaritons
Q-ONE aims to develop a novel quantum neural network in integrated photonic devices for generating and characterizing quantum states, advancing quantum technology through a reconfigurable platform.
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.