6533b85efe1ef96bd12bfd5e

RESEARCH PRODUCT

Quantum entanglement of identical particles by standard information-theoretic notions

Giuseppe CompagnoRosario Lo Franco

subject

Identical ParticleQuantum informationPartial traceFOS: Physical sciencesQuantum information; Quantum mechanics; Identical Particles; EntanglementQuantum entanglement01 natural sciencesSettore FIS/03 - Fisica Della MateriaArticle010305 fluids & plasmasEntanglementTheoretical physics0103 physical sciencesQuantum information010306 general physicsWave functionQuantumBosonPhysicsQuantum PhysicsMultidisciplinaryQuantum mechanicSecond quantizationQuantum Physics (quant-ph)Identical particles

description

Quantum entanglement of identical particles is essential in quantum information theory. Yet, its correct determination remains an open issue hindering the general understanding and exploitation of many-particle systems. Operator-based methods have been developed that attempt to overcome the issue. We introduce a state-based method which, as second quantization, does not label identical particles and presents conceptual and technical advances compared to the previous ones. It establishes the quantitative role played by arbitrary wave function overlaps, local measurements and particle nature (bosons or fermions) in assessing entanglement by notions commonly used in quantum information theory for distinguishable particles, like partial trace. Our approach furthermore shows that bringing identical particles into the same spatial location functions as an entangling gate, providing fundamental theoretical support to recent experimental observations with ultracold atoms. These results pave the way to set and interpret experiments for utilizing quantum correlations in realistic scenarios where overlap of particles can count, as in Bose-Einstein condensates, quantum dots and biological molecular aggregates.

yearjournalcountryeditionlanguage
2016-02-09Scientific Reports
10.1038/srep20603http://dx.doi.org/10.1038/srep20603