Paper

{
  "raw_xml": "<entry>\n    <id>http://arxiv.org/abs/2603.05886v1</id>\n    <title>Casimir-Polder potential on an excited atom near an atomic array</title>\n    <updated>2026-03-06T04:09:54Z</updated>\n    <link href='https://arxiv.org/abs/2603.05886v1' rel='alternate' type='text/html'/>\n    <link href='https://arxiv.org/pdf/2603.05886v1' rel='related' title='pdf' type='application/pdf'/>\n    <summary>We develop a microscopic description of the fluctuation-mediated Casimir-Polder (CP) shifts on a 'test' two-level atom placed near a two-dimensional atomic array of two-level atoms. We derive the resonant and off-resonant CP potentials experienced by the excited test atom using fourth-order perturbation theory, under the assumption that the test atom resonance is far detuned from those of the array atoms. The total potential on the test atom can be described as the sum of the pairwise resonant and off-resonant potentials resulting from its interaction with the individual atoms of the array. We analyze the asymptotic scaling of CP shifts as a function of the test atom-array separation, and its dependence on various system parameters: array spacing and size, and dipole orientation of the array atoms. Our results bridge the description of CP potential across two distinct regimes: (i) from a single-atom limit where we recover the well-known two-atom Van der Waals potential, (ii) to a macroscopic boundary limit, where we demonstrate new asymptotic scaling laws. We demonstrate that these scaling laws can be tuned via the microscopic parameters of the atomic array, establishing atomically-controlled arrays as a versatile platform for tailoring fluctuation-induced QED phenomena.</summary>\n    <category scheme='http://arxiv.org/schemas/atom' term='quant-ph'/>\n    <published>2026-03-06T04:09:54Z</published>\n    <arxiv:primary_category term='quant-ph'/>\n    <author>\n      <name>Annyun Das</name>\n    </author>\n    <author>\n      <name>Kanu Sinha</name>\n    </author>\n  </entry>"
}