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Quantum many-body physics with ultracold polar molecules: Nanostructured potential barriers and interactions

Andreas Kruckenhauser, Lukas M. Sieberer, Luigi De Marco, Jun-Ru Li, Kyle Matsuda, William G. Tobias, Giacomo Valtolina, Jun Ye, Ana María Rey, М. А. Баранов, P. Zoller

2020Physical review. A/Physical review, A23 citationsDOIOpen Access PDF

Abstract

We design dipolar quantum many-body Hamiltonians that will facilitate the realization of exotic quantum phases under current experimental conditions achieved for polar molecules. The main idea is to modulate both single-body potential barriers and two-body dipolar interactions on a spatial scale of tens of nanometers to strongly enhance energy scales and, therefore, relax temperature requirements for observing new quantum phases of engineered many-body systems. We consider and compare two approaches. In the first, nanoscale barriers are generated with standing-wave optical light fields exploiting optical nonlinearities. In the second, static electric-field gradients in combination with microwave dressing are used to write nanostructured spatial patterns on the induced electric dipole moments, and thus dipolar interactions. We study the formation of interlayer and interface bound states of molecules in these configurations, and provide detailed estimates for binding energies and expected losses for present experimental setups.

Topics & Concepts

DipoleQuantumPhysicsRealization (probability)PolarMicrowaveChemical polarityElectric fieldElectric dipole momentNanometreNanotechnologyChemical physicsMaterials scienceQuantum mechanicsOpticsStatisticsMathematicsCold Atom Physics and Bose-Einstein CondensatesQuantum Information and CryptographyStrong Light-Matter Interactions
Quantum many-body physics with ultracold polar molecules: Nanostructured potential barriers and interactions | Litcius