Litcius/Paper detail

Towards communication in a curved spacetime geometry

Qasem Exirifard, Eric Culf, Ebrahim Karimi

2021Communications Physics26 citationsDOIOpen Access PDF

Abstract

Abstract The current race in quantum communication – endeavouring to establish a global quantum network – must account for special and general relativistic effects. The well-studied general relativistic effects include Shapiro time-delay, gravitational lensing, and frame dragging which all are due to how a mass distribution alters geodesics. Here, we report how the curvature of spacetime geometry affects the propagation of information carriers along an arbitrary geodesic. An explicit expression for the distortion onto the carrier wavefunction in terms of the Riemann curvature is obtained. Furthermore, we investigate this distortion for anti de Sitter and Schwarzschild geometries. For instance, the spacetime curvature causes a 0.10 radian phase-shift for communication between Earth and the International Space Station on a monochromatic laser beam and quadrupole astigmatism; can cause a 12.2% cross-talk between structured modes traversing through the solar system. Our finding shows that this gravitational distortion is significant, and it needs to be either pre- or post-corrected at the sender or receiver to retrieve the information.

Topics & Concepts

PhysicsSpacetimeClassical mechanicsCurvatureMinkowski spaceWave packetSchwarzschild radiusQuantum field theory in curved spacetimeGeometryGravitationGravitational waveQuantum mechanicsGeneral relativityDistortion (music)Linearized gravityDifferential geometryCurved spaceMathematicsFrame of referenceTheoretical physicsRelativity and Gravitational TheoryQuantum Electrodynamics and Casimir EffectQuantum Mechanics and Applications