# Floquet engineering of optical lattices with spatial features and   periodicity below the diffraction limit

**Authors:** S. Subhankar, P. Bienias, P. Titum, T-C. Tsui, Y. Wang, A. V., Gorshkov, S. L. Rolston, J. V. Porto

arXiv: 1906.07646 · 2019-10-24

## TL;DR

This paper introduces a Floquet engineering framework to create optical lattices with spatial features below the diffraction limit by time-averaging over configurations of a 1D optical Kronig-Penney lattice, enabling subwavelength control.

## Contribution

It presents a novel Floquet-based method for stroboscopically engineering subwavelength optical lattices using dark state manipulation in ultracold atoms.

## Key findings

- A $$-spaced lattice can be synthesized with realistic parameters.
- Identifies mechanisms limiting lattice lifetimes.
- Demonstrates adiabatic loading into the ground band.

## Abstract

Floquet engineering or coherent time periodic driving of quantum systems has been successfully used to synthesize Hamiltonians with novel properties. In ultracold atomic systems, this has led to experimental realizations of artificial gauge fields, topological band structures, and observation of dynamical localization, to name just a few. Here we present a Floquet-based framework to stroboscopically engineer Hamiltonians with spatial features and periodicity below the diffraction limit of light used to create them by time-averaging over various configurations of a 1D optical Kronig-Penney (KP) lattice. The KP potential is a lattice of narrow subwavelength barriers spaced by half the optical wavelength ($\lambda/2$) and arises from the non-linear optical response of the atomic dark state. Stroboscopic control over the strength and position of this lattice requires time-dependent adiabatic manipulation of the dark state spin composition. We investigate adiabaticity requirements and shape our time-dependent light fields to respect the requirements. We apply this framework to show that a $\lambda/4$-spaced lattice can be synthesized using realistic experimental parameters as an example, discuss mechanisms that limit lifetimes in these lattices, explore candidate systems and their limitations, and treat adiabatic loading into the ground band of these lattices.

## Full text

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## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/1906.07646/full.md

## References

42 references — full list in the complete paper: https://tomesphere.com/paper/1906.07646/full.md

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Source: https://tomesphere.com/paper/1906.07646