Optical contrasts in microscopy are sensitive to light polarization, whose interaction with
molecular dipoles provides an important lever for probing molecular orientation. Polarization …

Probing light–matter interaction at the nanometer scale is one of the most fascinating topics
of modern optics. Its importance is underlined by the large span of fields in which such …

Estimating the orientation and 3D position of rotationally constrained emitters with
localization microscopy typically requires polarization splitting or a large engineered Point …

Single-molecule localization microscopy provides insights into the nanometer-scale spatial
organization of proteins in cells, however it does not provide information on their …

Precisely measuring the three-dimensional position and orientation of individual
fluorophores is challenging due to the substantial photon shot noise in single-molecule …

Single molecule localization microscopy (SMLM) has the potential to resolve structural
details of biological samples at the nanometer length scale. Compared to room temperature …

The dipole orientation of fluorescent molecules reveals the structural organization at the
subcellular level, and imaging its distribution is important for fundamental cell biology …

Super-resolution microscopy has catalyzed valuable insights into the sub-cellular,
mechanistic details of many different biological processes across a wide range of cell types …

Voltage imaging in cells requires high-speed recording of small fluorescent signals, often
leading to low signal/noise ratios. Because voltage indicators are membrane bound, their …

The precise spatial localization of single molecules in three dimensions is an important
basis for single molecule localization microscopy (SMLM) and tracking. At distances up to a …