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Main Authors: Prakash, Satyam, Vudayagiri, Ashok S
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.07512
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author Prakash, Satyam
Vudayagiri, Ashok S
author_facet Prakash, Satyam
Vudayagiri, Ashok S
contents While generating ultracold plasma (UCP) by photoinization of laser-cooled atoms, only a small fraction of atoms are ionized, and the remaining neutrals interact with the electrons present therein. These interactions, in addition to the Coulomb interactions between ions and electrons, cause phenomena such as ionization of Rydberg atoms and three body recombination, all of which affect the overall behaviour of the ultracold plasma. We had earlier developed a quantum treatment to analyze these interactions and investigated the ionization of Rydberg atoms in Cesium, which showed good agreement with measured results. We now extend it to other atomic species to investigate Rydberg ionization, and other effects such as three-body recombination and a resulting additional `quantum pressure' which causes a faster expansion of the UCP. Our results successfully explain experimental observations which were hitherto deemed as `anomalies'.
format Preprint
id arxiv_https___arxiv_org_abs_2603_07512
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Effect of dipole interactions on the properties of an expanding ultracold plasma: A study using quantum mechanical scattering theory
Prakash, Satyam
Vudayagiri, Ashok S
Atomic Physics
While generating ultracold plasma (UCP) by photoinization of laser-cooled atoms, only a small fraction of atoms are ionized, and the remaining neutrals interact with the electrons present therein. These interactions, in addition to the Coulomb interactions between ions and electrons, cause phenomena such as ionization of Rydberg atoms and three body recombination, all of which affect the overall behaviour of the ultracold plasma. We had earlier developed a quantum treatment to analyze these interactions and investigated the ionization of Rydberg atoms in Cesium, which showed good agreement with measured results. We now extend it to other atomic species to investigate Rydberg ionization, and other effects such as three-body recombination and a resulting additional `quantum pressure' which causes a faster expansion of the UCP. Our results successfully explain experimental observations which were hitherto deemed as `anomalies'.
title Effect of dipole interactions on the properties of an expanding ultracold plasma: A study using quantum mechanical scattering theory
topic Atomic Physics
url https://arxiv.org/abs/2603.07512