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Our novel technology is optimised for scalability and tunability

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Highly tunable optically addressable qubits

Qubits are optically addressable spins in carbene molecules embedded in a chemically tunable molecular crystal matrix

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Rapid iterative fabrication in quantum thin films

Modern organic chemistry enables rapid design and fabrication cycles, embedding qubits in <20nm quantum thin films

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Scalability through silicon photonics

Compatibility with existing silicon-based wafer technology enables rapid and cost effective scalability

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Highly tunable optically addressable qubits

Our photoactive carbene molecules are embedded in an inert host matrix forming a <20nm molecular crystal thin film

The optically addressable electron spin enables photon-based entanglement, while deterministic nuclear spins serve as qubits

The physical properties are NV-center-like, with a triplet ground state with long relaxation and coherence times

Yet, we achieve an unprecedented degree of tunability through our organic chemistry based design and fabrication approach

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Inert host molecule

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Photoactive carbene carrying optically addressable spin qubit

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Rapid iterative fabrication in quantum thin films

Compatibility with on-chip waveguides unlocks scalable entanglement between qubits via photonic coupling

Targeted design of qubit / matrix molecule combinations and dopant levels allow tunable control over emitted photon wavelengths (400-700nm) and number of nuclear spin qubits

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Scalability through silicon photonics

NVision’s quantum computing platform PIQ|C> is natively designed to integrate with one of the world’s most successful technologies and ecosystems:
Silicon-based wafer technology
 
Our highly tunable quantum thin films integrate straightforwardly with CMOS
 
The spin-photon coupling of our qubits enables highly entangled states via optical waveguides

What sets us apart?

Unlike most other technologies, our qubits achieve high quantum yield while also allowing high degrees of tunability

Individually tuned matrix and dopants yield deterministic nuclear-spin registers: an atomic-precision environmen

Our qubits’ photoemission matching SiN/Si waveguides unlocks scalable on-chip quantum operations 

Fast organic chemistry synthesis and electronic/magnetic property prediction shortens iteration cycles to weeks

Compatibility with silicon technology (e. g. CMOS compatible thin-film deposition) unlocks a large, mature ecosystem

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