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Entanglement significantly enhances quantum sensing for particle trajectory mapping. Using entangled sensors, perfect trajectory discrimination is achieved in one shot, unlike unentangled sensors requiring multiple attempts.

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Area of Science:

  • Quantum Information Science
  • Experimental High Energy Physics
  • Dark Matter Searches

Background:

  • Particle trajectory mapping is crucial for high energy physics experiments and dark matter detection.
  • Quantum sensing protocols utilize multiqubit sensor arrays for trajectory inference.
  • The particle-qubit interaction strength (θ) is a key parameter in these protocols.

Purpose of the Study:

  • To investigate the role of entanglement in improving quantum sensing for particle trajectory mapping.
  • To determine if entanglement can reduce the required particle-qubit interaction strength for accurate trajectory discrimination.
  • To analyze the performance of entangled versus unentangled sensors in realistic, non-ideal conditions.

Main Methods:

  • Quantum sensing protocol using projective measurements on a multiqubit sensor array.
  • Theoretical analysis comparing the performance of entangled and unentangled sensor arrays.
  • Simulation of realistic scenarios with continuous variation in particle-qubit interaction strength (e.g., Gaussian laser pulse).

Main Results:

  • Entanglement dramatically reduces the particle-qubit interaction strength (θ) needed for perfect trajectory discrimination.
  • Unentangled sensors require logarithmic repetitions (Θ[log(1/ε)]) for ε error probability, while entangled sensors achieve zero error in a single shot.
  • Entanglement enhances trajectory sensing even when θ varies continuously across qubits.

Conclusions:

  • Entanglement is a powerful resource for enhancing quantum trajectory sensing.
  • Single-shot, high-fidelity particle trajectory discrimination is achievable with entangled quantum sensors.
  • The findings have significant implications for improving sensitivity in high energy physics and dark matter detection experiments.