PIFLUX uses counter-propagating gap plasmons interfering with a normal-incidence field to create a phase-tunable illumination pattern that achieves MINFLUX-level localization precision while doubling SIMFLUX performance over an extended field of view.
Nanometer resolution imaging and tracking of fluorescent molecules with minimal photon fluxes
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abstract
We introduce MINFLUX, a concept for localizing photon emitters in space. By probing the emitter with a local intensity minimum of excitation light, MINFLUX minimizes the fluorescence photons needed for high localization precision. A 22-fold reduction of photon detections over that required in popular centroid-localization is demonstrated. In superresolution microscopy, MINFLUX attained ~1 nm precision, resolving molecules only 6 nm apart. Tracking single fluorescent proteins by MINFLUX increased the temporal resolution and the localizations per trace by 100-fold, as demonstrated with diffusing 30S ribosomal subunits in living E. coli. Since conceptual limits have not been reached, we expect this localization modality to break new ground for observing the dynamics, distribution, and structure of macromolecules in living cells and beyond.
fields
physics.optics 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
citing papers explorer
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Plasmon-Enabled High-Precision Single Molecule Localization Microscopy over an Extended Field of View
PIFLUX uses counter-propagating gap plasmons interfering with a normal-incidence field to create a phase-tunable illumination pattern that achieves MINFLUX-level localization precision while doubling SIMFLUX performance over an extended field of view.