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Fusion-based quantum computation.

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Fusion-based quantum computation offers a fault-tolerant model using photonic systems. This approach utilizes entangling measurements (fusions) and a quantum error correction protocol, achieving a higher error threshold than previous schemes.

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Area of Science:

  • Quantum Computing
  • Photonics
  • Quantum Error Correction

Background:

  • Standard quantum computing relies on deterministic unitary entangling gates, which are challenging to implement in photonic systems.
  • Photonic systems offer natural primitives like entangling measurements (fusions) that can be leveraged for computation.

Purpose of the Study:

  • To introduce fusion-based quantum computation, a model tailored for fault-tolerant quantum computing using readily available photonic primitives.
  • To demonstrate that this model can achieve a higher error threshold compared to existing schemes.

Main Methods:

  • Utilizing entangling measurements (fusions) on qubits within small, constant-sized entangled resource states.
  • Integrating probabilistic photonic gates and errors directly into a quantum error correction protocol.
  • Developing a ballistic scheme to manage photon loss during fusion operations.

Main Results:

  • The fusion-based model achieves a higher fault-tolerance threshold than previously reported schemes.
  • The proposed ballistic scheme tolerates a 10.4% photon loss probability per fusion (2.7% per photon).
  • The architecture is highly modular with reduced classical processing demands.

Conclusions:

  • Fusion-based quantum computation provides a viable and robust model for fault-tolerant quantum computing in photonic systems.
  • This approach effectively handles probabilistic gates and photon loss through integrated error correction.
  • The modularity and efficiency offer significant advantages over prior photonic quantum computing architectures.