Litcius/Paper detail

Distributed quantum sensing of multiple phases with fewer photons

Donghyun Kim, Seongjin Hong, Yong‐Su Kim, Yosep Kim, Seung-Woo Lee, Raphael C. Pooser, Kyunghwan Oh, Su‐Yong Lee, Changhyoup Lee, Hyang‐Tag Lim

2024Nature Communications46 citationsDOIOpen Access PDF

Abstract

Distributed quantum metrology has drawn intense interest as it outperforms the optimal classical counterparts in estimating multiple distributed parameters. However, most schemes so far have required entangled resources consisting of photon numbers equal to or more than the parameter numbers, which is a fairly demanding requirement as the number of nodes increases. Here, we present a distributed quantum sensing scenario in which quantum-enhanced sensitivity can be achieved with fewer photons than the number of parameters. As an experimental demonstration, using a two-photon entangled state, we estimate four phases distributed 3 km away from the central node, resulting in a 2.2 dB sensitivity enhancement from the standard quantum limit. Our results show that the Heisenberg scaling can be achieved even when using fewer photons than the number of parameters. We believe our scheme will open a pathway to perform large-scale distributed quantum sensing with currently available entangled sources.

Topics & Concepts

PhotonQuantum metrologyQuantum sensorPhysicsQuantumScalingSensitivity (control systems)Heisenberg limitQuantum limitQuantum networkComputer scienceNode (physics)Limit (mathematics)Quantum mechanicsQuantum computerStatistical physicsMathematicsElectronic engineeringMathematical analysisEngineeringGeometryQuantum Information and CryptographyMechanical and Optical ResonatorsNeural Networks and Reservoir Computing