Bilocal versus non-bilocal correlations in entanglement swapping experiments (1112.4502v1)

Abstract: Entanglement swapping is a process by which two initially independent quantum systems can become entangled and generate nonlocal correlations. To characterize such correlations, we compare them to those predicted by bilocal models, where systems that are initially independent are described by uncorrelated states. We extend in this paper the analysis of bilocal correlations initiated in [Phys. Rev. Lett. 104, 170401 (2010)]. In particular, we derive new Bell-type inequalities based on the bilocality assumption in different scenarios, we study their possible quantum violations, and analyze their resistance to experimental imperfections. The bilocality assumption, being stronger than Bell's standard local causality assumption, lowers the requirements for the demonstration of quantumness in entanglement swapping experiments.

Analyzing Bilocal Versus Non-Bilocal Correlations in Entanglement Swapping Experiments

The paper by Branciard et al. explores the concept of bilocality in the context of entanglement swapping experiments, presenting a comprehensive paper on distinguishing bilocal from non-bilocal correlations. The authors extend the analysis initially introduced in Phys. Rev. Lett. 104, 170401 (2010), by deriving new Bell-type inequalities contingent upon the bilocality assumption, examining their quantum violations, and analyzing their robustness against experimental imperfections. This paper is particularly relevant as quantum communication networks, often relying on entanglement swapping and quantum repeaters, gain attention for their ability to demonstrate advanced quantum phenomena and serve practical information processing functions.

Bilocality and Its Implication

Bilocality is introduced as a refinement of Bell's locality condition, considering scenarios involving multiple independent sources. The authors define bilocality in setups where two or more initially independent subsystems become entangled through joint measurements, without an overarching entangled state governing all systems. This definition leads to a stronger form of Bell inequalities, which lower experimental demands to demonstrate quantumness compared to traditional Bell tests. The paper explores explicit representations of bilocal models, leveraging a non-linear constraint that surpasses the standard locality assumptions by incorporating independence of sources into entanglement swapping scenarios.

Experimental Considerations and Results

The research rigorously develops nonlinear inequalities that any bilocal correlations must satisfy and demonstrates that quantum entanglement swapping can violate these inequalities under certain conditions. For instance, in standard entanglement swapping scenarios involving Bell state measurements, bilocal inequalities are violated at visibilities above 50%, whereas traditional Bell nonlocality requires higher visibilities (>66%).

The paper explores multiple configurations, including complete and partial Bell state measurements, revealing how different measurement protocols impact non-bilocality demonstration. For example, while complete Bell state measurements showcase non-bilocality benefits at lower visibilities, partial measurements align closely with standard tests' needs unless optimized settings are applied.

Robustness and Extensions

Critical attention is given to analyzing the resilience of these non-bilocal quantum correlations against noise and detection inefficiencies. The results point to a bifold characterization where bilocal correlations are more robust to noise than Bell nonlocal correlations, highlighting the potential for reduced requirements in demonstrating quantum characteristics in practical setups.

Furthermore, the paper speculates the extension to larger networks and more complex configurations, suggesting that the implications of bilocality could advance the understanding of nonlocal properties in extensive quantum networks. The triangulation of these findings serves as a pivotal point for guiding future experiments toward demonstrating quantum features without the rigor of perfect conditions prevalent in Bell test configurations.

Future Trajectories

The exploration paves the way towards a broader application of bilocal correlations in quantum information science. With ongoing advancements in quantum repeaters and the increasing complexity of networked quantum systems, the paper establishes foundational notions that could be instrumental in the development and analysis of future quantum networks.

In conclusion, Branciard et al.'s work offers notable insight into the characteristics of bilocal versus non-bilocal correlations, providing a clearer path for demonstrating quantum phenomena while addressing typical experimental limitations such as detection inefficiencies and source noise. The prospect of leveraging bilocality in practical applications renders this research a pertinent stepping stone for developing realistic quantum communication systems and furthering theoretical understanding in quantum mechanics.