Multi-level Zeeman-resolved Rydberg EIT extracts 3D MW polarization amplitudes and relative phases self-calibrated from one spectrum via internal closed interferometric loops.
Quantum-enabled complete RF-polarimetry with an optically-wired atomic sensor
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abstract
Rydberg atomic electrometry leverages the extreme sensitivity of highly excited atoms for calibration-free electric field measurements. The technique uses a non-metallic vapor cell to link properties of an RF field to a spectroscopic readout in the optical domain. Most demonstrations have so far focused on detecting linearly-polarized fields, for which the induced splitting of dressed atomic levels is rotationally invariant. Here we report on Rydberg atomic measurements of RF fields in a general state of polarization (SOP) which we map onto the Poincar\'{e} sphere through spectroscopic fingerprints. For a Stokes vector circumnavigating a Poincar\'e sphere meridian, we witness a continuous transformation of the atomic eigenenergy spectrum. Because the relative positions of eigenenergies are locked in place by quantization of angular momentum, the framework is universal and calibration free. We provide a specific demonstration in rubidium, which generalizes to all systems with a single valence electron.
fields
physics.atom-ph 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Self-calibrated multiparameter measurement of three-dimensional microwave fields
Multi-level Zeeman-resolved Rydberg EIT extracts 3D MW polarization amplitudes and relative phases self-calibrated from one spectrum via internal closed interferometric loops.