Litcius/Paper detail

Quantum Simulations with Complex Geometries and Synthetic Gauge Fields in a Trapped Ion Chain

Tom Manovitz, Yotam Shapira, Nitzan Akerman, Ady Stern, Roee Ozeri

2020PRX Quantum26 citationsDOIOpen Access PDF

Abstract

In recent years, arrays of atomic ions in a linear radio-frequency trap have proven to be a particularly successful platform for quantum simulation. However, a wide range of quantum models and phenomena have, so far, remained beyond the reach of such simulators. In this work we introduce a technique that can substantially extend this reach using an external field gradient along the ion chain and a global, uniform driving field. The technique can be used to generate both static and time-varying synthetic gauge fields in a linear chain of trapped ions, and enables continuous simulation of a variety of coupling geometries and topologies, including periodic boundary conditions and high-dimensional Hamiltonians. We describe the technique, derive the corresponding effective Hamiltonian, propose a number of variations, and discuss the possibility of scaling to quantum-advantage-sized simulators. Additionally, we suggest several possible implementations and briefly examine two: the Aharonov-Bohm ring and the frustrated triangular ladder.

Topics & Concepts

Chain (unit)ScalingQuantumPhysicsGauge (firearms)Coupling (piping)IonField (mathematics)Linear scaleWork (physics)Periodic boundary conditionsRange (aeronautics)Boundary (topology)Trapped ion quantum computerStatistical physicsVariety (cybernetics)Boundary value problemQuantum simulatorQuantum mechanicsQuantum entanglementGauge theoryScale (ratio)Ion trapClassical mechanicsAtom opticsRing (chemistry)Energetic neutral atomScaling limitBasis (linear algebra)Computational physicsQuantum Information and CryptographyQuantum chaos and dynamical systemsCold Atom Physics and Bose-Einstein Condensates