Injection spectroscopy of momentum state lattices

Sai Naga Manoj Paladugu; Tao Chen; Fangzhao Alex An; Bo Yan; Bryce Gadway

doi:10.1038/s42005-024-01526-8

Injection spectroscopy of momentum state lattices

Sai Naga Manoj Paladugu
, Tao Chen
, Fangzhao Alex An
, Bo Yan
, Bryce Gadway

Physics

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

7 Scopus citations

Abstract

The energy spectrum of quantum systems contain a wealth of information about their underlying properties. Spectroscopic techniques, especially those with access to spatially resolved measurements, can be challenging to implement in real-space systems of cold atoms in optical lattices. Here we explore a technique for probing energy spectra in synthetic lattices that is analogous to scanning tunneling microscopy. Using one-dimensional synthetic lattices of coupled atomic momentum states, we explore this spectroscopic technique and observe qualitative agreement between the measured and simulated energy spectra for small two- and three-site lattices as well as a uniform many-site lattice. Finally, through simulations, we show that this technique should allow for the exploration of the topological bands and the fractal energy spectrum of the Hofstadter model as realized in synthetic lattices.

Original language	English (US)
Article number	39
Journal	Communications Physics
Volume	7
Issue number	1
DOIs	https://doi.org/10.1038/s42005-024-01526-8
State	Published - Dec 2024

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1038/s42005-024-01526-8

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title = "Injection spectroscopy of momentum state lattices",

abstract = "The energy spectrum of quantum systems contain a wealth of information about their underlying properties. Spectroscopic techniques, especially those with access to spatially resolved measurements, can be challenging to implement in real-space systems of cold atoms in optical lattices. Here we explore a technique for probing energy spectra in synthetic lattices that is analogous to scanning tunneling microscopy. Using one-dimensional synthetic lattices of coupled atomic momentum states, we explore this spectroscopic technique and observe qualitative agreement between the measured and simulated energy spectra for small two- and three-site lattices as well as a uniform many-site lattice. Finally, through simulations, we show that this technique should allow for the exploration of the topological bands and the fractal energy spectrum of the Hofstadter model as realized in synthetic lattices.",

author = "Paladugu, \{Sai Naga Manoj\} and Tao Chen and An, \{Fangzhao Alex\} and Bo Yan and Bryce Gadway",

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doi = "10.1038/s42005-024-01526-8",

language = "English (US)",

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T1 - Injection spectroscopy of momentum state lattices

AU - Paladugu, Sai Naga Manoj

AU - Chen, Tao

AU - An, Fangzhao Alex

AU - Yan, Bo

AU - Gadway, Bryce

PY - 2024/12

Y1 - 2024/12

N2 - The energy spectrum of quantum systems contain a wealth of information about their underlying properties. Spectroscopic techniques, especially those with access to spatially resolved measurements, can be challenging to implement in real-space systems of cold atoms in optical lattices. Here we explore a technique for probing energy spectra in synthetic lattices that is analogous to scanning tunneling microscopy. Using one-dimensional synthetic lattices of coupled atomic momentum states, we explore this spectroscopic technique and observe qualitative agreement between the measured and simulated energy spectra for small two- and three-site lattices as well as a uniform many-site lattice. Finally, through simulations, we show that this technique should allow for the exploration of the topological bands and the fractal energy spectrum of the Hofstadter model as realized in synthetic lattices.

AB - The energy spectrum of quantum systems contain a wealth of information about their underlying properties. Spectroscopic techniques, especially those with access to spatially resolved measurements, can be challenging to implement in real-space systems of cold atoms in optical lattices. Here we explore a technique for probing energy spectra in synthetic lattices that is analogous to scanning tunneling microscopy. Using one-dimensional synthetic lattices of coupled atomic momentum states, we explore this spectroscopic technique and observe qualitative agreement between the measured and simulated energy spectra for small two- and three-site lattices as well as a uniform many-site lattice. Finally, through simulations, we show that this technique should allow for the exploration of the topological bands and the fractal energy spectrum of the Hofstadter model as realized in synthetic lattices.

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JF - Communications Physics

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ER -

Injection spectroscopy of momentum state lattices

Abstract

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