Single ultracold rubidium atom trapped in the evanescent field of an integrated silicon-nitride microring resonator, achieving single-atom cooperativity exceeding unity.
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Direct spectroscopic measurement of Casimir-Polder force-induced kHz shifts on strontium atoms in the intermediate regime agrees with QED but differs from short- and long-range approximations.
Near-field probing of trapped atoms is inherently transient due to probe-induced heating that reduces coupling strength via increased position spread.
citing papers explorer
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Single-atom trapping in the evanescent field of an integrated photonic resonator
Single ultracold rubidium atom trapped in the evanescent field of an integrated silicon-nitride microring resonator, achieving single-atom cooperativity exceeding unity.
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Spectroscopic measurement of the Casimir-Polder force in the intermediate regime
Direct spectroscopic measurement of Casimir-Polder force-induced kHz shifts on strontium atoms in the intermediate regime agrees with QED but differs from short- and long-range approximations.
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Limits of Stable Near-Field Probing in Nanophotonic Traps
Near-field probing of trapped atoms is inherently transient due to probe-induced heating that reduces coupling strength via increased position spread.