Three-dimensional imaging of single atoms in an optical lattice via helical point-spread-function engineering

Tangi Legrand; Falk-Richard Winkelmann; Wolfgang Alt; Dieter Meschede; Andrea Alberti; Carrie A. Weidner

doi:10.1103/PhysRevA.109.033304

Three-dimensional imaging of single atoms in an optical lattice via helical point-spread-function engineering

Tangi Legrand, Falk-Richard Winkelmann, Wolfgang Alt, Dieter Meschede, Andrea Alberti^*, Carrie A. Weidner^*

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

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Abstract

We demonstrate a method for determining the three-dimensional location of single atoms in a quantum gas microscopy system using a phase-only spatial light modulator to modify the point-spread function of the high-resolution imaging system. Here, the typical diffracted spot generated by a single atom as a point source is modified to a double spot that rotates as a function of the atom's distance from the focal plane of the imaging system. We present and numerically validate a simple model linking the rotation angle of the point-spread function with the distance to the focal plane. We show that, when aberrations in the system are carefully calibrated and compensated for, this method can be used to determine an atom's position to within a single lattice site in a single experimental image, extending quantum simulation with microscopy systems further into the regime of three dimensions.

Original language	English
Article number	033304
Number of pages	14
Journal	Physical Review A
Volume	109
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevA.109.033304
Publication status	Published - 5 Mar 2024

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© 2024 American Physical Society.

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https://arxiv.org/abs/2312.05341

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abstract = "We demonstrate a method for determining the three-dimensional location of single atoms in a quantum gas microscopy system using a phase-only spatial light modulator to modify the point-spread function of the high-resolution imaging system. Here, the typical diffracted spot generated by a single atom as a point source is modified to a double spot that rotates as a function of the atom's distance from the focal plane of the imaging system. We present and numerically validate a simple model linking the rotation angle of the point-spread function with the distance to the focal plane. We show that, when aberrations in the system are carefully calibrated and compensated for, this method can be used to determine an atom's position to within a single lattice site in a single experimental image, extending quantum simulation with microscopy systems further into the regime of three dimensions.",

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AU - Legrand, Tangi

AU - Winkelmann, Falk-Richard

AU - Alt, Wolfgang

AU - Meschede, Dieter

AU - Alberti, Andrea

AU - Weidner, Carrie A.

PY - 2024/3/5

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N2 - We demonstrate a method for determining the three-dimensional location of single atoms in a quantum gas microscopy system using a phase-only spatial light modulator to modify the point-spread function of the high-resolution imaging system. Here, the typical diffracted spot generated by a single atom as a point source is modified to a double spot that rotates as a function of the atom's distance from the focal plane of the imaging system. We present and numerically validate a simple model linking the rotation angle of the point-spread function with the distance to the focal plane. We show that, when aberrations in the system are carefully calibrated and compensated for, this method can be used to determine an atom's position to within a single lattice site in a single experimental image, extending quantum simulation with microscopy systems further into the regime of three dimensions.

AB - We demonstrate a method for determining the three-dimensional location of single atoms in a quantum gas microscopy system using a phase-only spatial light modulator to modify the point-spread function of the high-resolution imaging system. Here, the typical diffracted spot generated by a single atom as a point source is modified to a double spot that rotates as a function of the atom's distance from the focal plane of the imaging system. We present and numerically validate a simple model linking the rotation angle of the point-spread function with the distance to the focal plane. We show that, when aberrations in the system are carefully calibrated and compensated for, this method can be used to determine an atom's position to within a single lattice site in a single experimental image, extending quantum simulation with microscopy systems further into the regime of three dimensions.

U2 - 10.1103/PhysRevA.109.033304

DO - 10.1103/PhysRevA.109.033304

M3 - Article (Academic Journal)

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JO - Physical Review A

JF - Physical Review A

IS - 3

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ER -

Three-dimensional imaging of single atoms in an optical lattice via helical point-spread-function engineering

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