Litcius/Paper detail

Superresolution Microscopy of Optical Fields Using Tweezer-Trapped Single Atoms

Emma Deist, Justin A. Gerber, Yue-Hui Lu, Johannes Zeiher, Dan M. Stamper-Kurn

2022Physical Review Letters43 citationsDOIOpen Access PDF

Abstract

We realize a scanning probe microscope using single trapped ^{87}Rb atoms to measure optical fields with subwavelength spatial resolution. Our microscope operates by detecting fluorescence from a single atom driven by near-resonant light and determining the ac Stark shift of an atomic transition from other local optical fields via the change in the fluorescence rate. We benchmark the microscope by measuring two standing-wave Gaussian modes of a Fabry-Pérot resonator with optical wavelengths of 1560 and 781 nm. We attain a spatial resolution of 300 nm, which is superresolving compared to the limit set by the 780 nm wavelength of the detected light. Sensitivity to short length scale features is enhanced by adapting the sensor to characterize an optical field via the force it exerts on the atom.

Topics & Concepts

OpticsMicroscopeWavelengthOptical microscopeMicroscopyMaterials scienceNear-field scanning optical microscopeResolution (logic)PhysicsImage resolutionNear-field opticsResonatorFluorescence microscopeTemporal resolutionSuper-resolution microscopyOptoelectronicsAtom (system on chip)GaussianScanning tunneling microscopeOptical fieldField (mathematics)Optical phenomenaSensitivity (control systems)FluorescenceNear and far fieldMeasure (data warehouse)Molecular physicsVisible spectrumTracking (education)Mechanical and Optical ResonatorsQuantum optics and atomic interactionsCold Atom Physics and Bose-Einstein Condensates