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Radial Two-Dimensional Ion Crystals in a Linear Paul Trap

Marissa D’Onofrio, Yuanheng Xie, A. J. Rasmusson, Evangeline Wolanski, Jiafeng Cui, Philip Richerme

2021Physical Review Letters39 citationsDOIOpen Access PDF

Abstract

We experimentally study two-dimensional (2D) Coulomb crystals in the "radial-2D" phase of a linear Paul trap. This phase is identified by a 2D ion lattice aligned entirely with the radial plane and is created by imposing a large ratio of axial to radial trapping potentials. Using arrays of up to 19 ^{171}Yb^{+} ions, we demonstrate that the structural phase boundaries of such crystals are well described by the pseudopotential approximation, despite the time-dependent ion positions driven by intrinsic micromotion. We further observe that micromotion-induced heating of the radial-2D crystal is confined to the radial plane. Finally, we verify that the transverse motional modes, which are used in most ion-trap quantum simulation schemes, are well-predictable numerically and remain decoupled and cold in this geometry. Our results establish radial-2D ion crystals as a robust experimental platform for realizing a variety of theoretical proposals in quantum simulation and computation.

Topics & Concepts

PseudopotentialIonIon trappingIon trapTrappingPhysicsAtomic physicsCoulombTransverse planeCrystal (programming language)Lattice (music)Phase (matter)Plane (geometry)Trap (plumbing)Condensed matter physicsMolecular physicsQuantum mechanicsElectronGeometryStructural engineeringBiologyProgramming languageComputer scienceMathematicsEcologyMeteorologyAcousticsEngineeringCold Atom Physics and Bose-Einstein CondensatesQuantum Information and CryptographyQuantum optics and atomic interactions