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Complex quantum networks as structured environments: engineering and probing.

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We show how a single quantum probe can accurately detect spectral density and reconstruct the structure and topology of bosonic quantum networks. This method works for complex networks and engineered spectral properties.

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Area of Science:

  • Quantum physics
  • Network science
  • Information theory

Background:

  • Bosonic quantum networks are complex systems.
  • Probing their properties is challenging.

Purpose of the Study:

  • To develop a method for probing quantum network properties.
  • To engineer spectral density by altering network structure.
  • To reconstruct network topology and structure using a quantum probe.

Main Methods:

  • Utilizing a locally immersed quantum probe.
  • Analyzing spectral density detection.
  • Demonstrating network structure reconstruction.

Main Results:

  • Spectral density can be accurately detected for any network configuration.
  • Network structure can be fully reconstructed with a single probe.
  • Method validated on complex networks with engineered spectral densities.

Conclusions:

  • A single quantum probe is sufficient for comprehensive analysis of bosonic quantum networks.
  • The proposed method offers precise characterization of spectral density, structure, and topology.
  • This approach enables the study of complex quantum network configurations.