Near-resonant light scattering by an atom in a state-dependent trap

• Published in: arXiv.org
• Main Authors: Karanikolaou, Teresa D, Bettles, Robert J, Chang, Darrick E
• Format: Paper Journal Article
• Language: English
• Published: Ithaca Cornell University Library, arXiv.org 12.01.2024
• Subjects: Elastic scattering; Laser cooling; Light; Light scattering; Optical properties; Optical traps; Optics; Photons; Physics - Quantum Physics; Quantum optics; Resonant photons; Scattering cross sections
• ISSN: 2331-8422
• DOI: 10.48550/arxiv.2401.06753

The optical properties of a fixed atom are well-known and investigated. For example, the extraordinarily large cross section of a single atom as seen by a resonant photon is essential for quantum optical applications. Mechanical effects associated with light scattering are also well-studied, forming the basis of laser cooling and trapping, for example. Despite this, there is one fundamental problem that surprisingly has not been extensively studied, yet is relevant to a number of emerging quantum optics experiments. In these experiments, the ground state of the atom experiences a tight optical trap formed by far-off-resonant light, to facilitate efficient interactions with near-resonant light. However, the excited state might experience a different potential, or even be anti-trapped. Here, we systematically analyze the effects of unequal trapping on near-resonant atom-light interactions. In particular, we identify regimes where such trapping can lead to significant excess heating, and a reduction of total and elastic scattering cross sections associated with a decreased atom-photon interaction efficiency. Understanding these effects can be valuable for optimizing quantum optics platforms where efficient atom-light interactions on resonance are desired, but achieving equal trapping is not feasible.