Two-Dimensional Momentum State Lattices

Shraddha Agrawal; Sai Naga Manoj Paladugu; Bryce Gadway

doi:10.1103/PRXQuantum.5.010310

Two-Dimensional Momentum State Lattices

Shraddha Agrawal, Sai Naga Manoj Paladugu, Bryce Gadway

Eberly College of Science

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Building on the development of momentum state lattices (MSLs) over the past decade, we introduce a simple extension of this technique to higher dimensions. Based on the selective addressing of unique Bragg resonances in matter-wave systems, MSLs have enabled the realization of tight-binding models with tunable disorder, gauge fields, non-Hermiticity, and other features. Here, we examine and outline an experimental approach to building scalable and tunable tight-binding models in two dimensions describing the laser-driven dynamics of atoms in momentum space. Using numerical simulations, we highlight some of the simplest models and types of phenomena this system is well suited to address, including flat-band models with kinetic frustration and flux lattices supporting topological boundary states. Finally, we discuss many of the direct extensions to this model, including the introduction of disorder and non-Hermiticity, which will enable the exploration of new transport and localization phenomena in higher dimensions.

Original language	English (US)
Article number	010310
Journal	PRX Quantum
Volume	5
Issue number	1
DOIs	https://doi.org/10.1103/PRXQuantum.5.010310
State	Published - Jan 2024

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
General Computer Science
Mathematical Physics
General Physics and Astronomy
Applied Mathematics
Electrical and Electronic Engineering

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10.1103/PRXQuantum.5.010310

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title = "Two-Dimensional Momentum State Lattices",

abstract = "Building on the development of momentum state lattices (MSLs) over the past decade, we introduce a simple extension of this technique to higher dimensions. Based on the selective addressing of unique Bragg resonances in matter-wave systems, MSLs have enabled the realization of tight-binding models with tunable disorder, gauge fields, non-Hermiticity, and other features. Here, we examine and outline an experimental approach to building scalable and tunable tight-binding models in two dimensions describing the laser-driven dynamics of atoms in momentum space. Using numerical simulations, we highlight some of the simplest models and types of phenomena this system is well suited to address, including flat-band models with kinetic frustration and flux lattices supporting topological boundary states. Finally, we discuss many of the direct extensions to this model, including the introduction of disorder and non-Hermiticity, which will enable the exploration of new transport and localization phenomena in higher dimensions.",

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Two-Dimensional Momentum State Lattices

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