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Main Authors: Dardia, Anna R., Walker, Spencer, Bai, Yifei, Kousis, Petros, Landsman, Alexandra S., Weld, David M.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2606.00242
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_version_ 1866913174824943616
author Dardia, Anna R.
Walker, Spencer
Bai, Yifei
Kousis, Petros
Landsman, Alexandra S.
Weld, David M.
author_facet Dardia, Anna R.
Walker, Spencer
Bai, Yifei
Kousis, Petros
Landsman, Alexandra S.
Weld, David M.
contents Strong oscillating fields are expected to tear apart bound quantum states. Theoretical studies predict a striking reversal: that as the field intensity is raised above some threshold, bound states like atoms can become increasingly stable, accompanied by a spatial bifurcation of the bound state wavefunction. This strong field stabilization was predicted decades ago in the context of atoms in pulsed laser fields, but has resisted experimental observation due to extreme intensity requirements and theoretical controversy. Here we report the experimental observation of strong-field stabilization of a ground state, using trapped neutral atoms to emulate the dynamics of bound electrons in an extremely strong laser field. We image the predicted wavepacket bifurcation, measure an ionization rate non-monotonic in field amplitude, and map out the regime of stabilization. Stabilization persists down to surprisingly low drive frequencies, on the order of the lowest-energy excitations. These results confirm a long-standing prediction in extreme quantum dynamics, and showcase a complementary tool for probing strong-field phenomena near and beyond the frontier of current laser technology.
format Preprint
id arxiv_https___arxiv_org_abs_2606_00242
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Experimental observation of strong field stabilization
Dardia, Anna R.
Walker, Spencer
Bai, Yifei
Kousis, Petros
Landsman, Alexandra S.
Weld, David M.
Atomic Physics
Quantum Gases
Strong oscillating fields are expected to tear apart bound quantum states. Theoretical studies predict a striking reversal: that as the field intensity is raised above some threshold, bound states like atoms can become increasingly stable, accompanied by a spatial bifurcation of the bound state wavefunction. This strong field stabilization was predicted decades ago in the context of atoms in pulsed laser fields, but has resisted experimental observation due to extreme intensity requirements and theoretical controversy. Here we report the experimental observation of strong-field stabilization of a ground state, using trapped neutral atoms to emulate the dynamics of bound electrons in an extremely strong laser field. We image the predicted wavepacket bifurcation, measure an ionization rate non-monotonic in field amplitude, and map out the regime of stabilization. Stabilization persists down to surprisingly low drive frequencies, on the order of the lowest-energy excitations. These results confirm a long-standing prediction in extreme quantum dynamics, and showcase a complementary tool for probing strong-field phenomena near and beyond the frontier of current laser technology.
title Experimental observation of strong field stabilization
topic Atomic Physics
Quantum Gases
url https://arxiv.org/abs/2606.00242