Non-perturbative 2D spatial measurements of electric fields within a plasma sheath

Mykhailo Vorobiov, Rob Behary, Will Torg, Nicolas DeStefano, Saskia Mordijck, Edward Thomas, Saikat Chakraborty Thakur, Charles T. Fancher, Neel Malvania, Seth Aubin, Eugeniy E. Mikhailov, Irina Novikova·November 15, 2025

physics.plasm-phphysics.app-phAtomic Physicsphysics.opticsQuantum Physics

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Abstract

We introduce an all-optical quantum-enhanced diagnostic for electric fields in low-temperature plasmas. Trace amounts of rubidium vapor, added to argon plasma, allow us to produce spectrally narrow electric field-sensitive optical resonances via quantum optical effect of Rydberg electromagnetically induced transparency, and to non-invasively measure electric field in plasma with sensitivity exceeding 1 V/cm. By collecting fluorescence from the illuminated region of interest, we reconstruct a 2D spatial profile of the electric field magnitude with $30~μ$m resolution. As a proof-of-principle demonstration, we measured the changes in electric field within the plasma sheath surrounding a biased Langmuir probe tip. This method holds significant potential for studying sheath structures in low-temperature plasmas.

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Non-perturbative 2D spatial measurements of electric fields within a plasma sheath

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