We have developed a general approach for the calculation of the single molecule polarization correlation function C(t), which delivers a correlation of the emission dichroisms at time 0 and t. The approach is model independent and valid for general asymmetric top molecules. The key dynamic quantities of our analysis are the even-rank orientational correlation functions, the weighted sum of which yields C(t). We have demonstrated that the use of nonorthogonal schemes for the detection of the single molecule polarization responses makes it possible to manipulate the weighting coefficients in the expansion of C(t). Thus valuable information about the orientational correlation functions of the rank higher than the second can be extracted from C...
Within condensed matter, single fluorophores are sensitive probes of their chemical environments, bu...
A theory is presented that incorporates the effect of orientational correlations between luminescent...
$^{1}$ A. C. Albrecht, J. Mol. Spectry., 6, 84 (1961). $^{2}$ Y. N. Chiu, J. Chem. Phys., 46, 772 (1...
We have developed a general approach for the calculation of the single molecule polarization correla...
International audienceOptical contrasts in microscopy are sensitive to light polarization, whose int...
In single molecule orientation localization microscopy, aberrations cause changes in the shape of th...
Fluorescence polarization measurements in the condensed phase provide rich information on rotational...
Combining orientation estimation with localization microscopy opens up the possibility to analyze th...
We introduce new techniques for obtaining single-molecule orientation images and analyzing the reori...
Optical activity is the defining property of chiral materials that is essential for characterization...
Fluorescence polarization is widely used to assess the orientation/rotation of molecules, and the ex...
International audienceIn single molecule orientation localization microscopy, aberrations cause chan...
AbstractA new approach is presented for measuring the three-dimensional orientation of individual ma...
Single-molecule localization microscopy has been widely applied to count the number of biological mo...
The graphical representation of single-frequency phase-modulation fluorescence lifetime imaging data...
Within condensed matter, single fluorophores are sensitive probes of their chemical environments, bu...
A theory is presented that incorporates the effect of orientational correlations between luminescent...
$^{1}$ A. C. Albrecht, J. Mol. Spectry., 6, 84 (1961). $^{2}$ Y. N. Chiu, J. Chem. Phys., 46, 772 (1...
We have developed a general approach for the calculation of the single molecule polarization correla...
International audienceOptical contrasts in microscopy are sensitive to light polarization, whose int...
In single molecule orientation localization microscopy, aberrations cause changes in the shape of th...
Fluorescence polarization measurements in the condensed phase provide rich information on rotational...
Combining orientation estimation with localization microscopy opens up the possibility to analyze th...
We introduce new techniques for obtaining single-molecule orientation images and analyzing the reori...
Optical activity is the defining property of chiral materials that is essential for characterization...
Fluorescence polarization is widely used to assess the orientation/rotation of molecules, and the ex...
International audienceIn single molecule orientation localization microscopy, aberrations cause chan...
AbstractA new approach is presented for measuring the three-dimensional orientation of individual ma...
Single-molecule localization microscopy has been widely applied to count the number of biological mo...
The graphical representation of single-frequency phase-modulation fluorescence lifetime imaging data...
Within condensed matter, single fluorophores are sensitive probes of their chemical environments, bu...
A theory is presented that incorporates the effect of orientational correlations between luminescent...
$^{1}$ A. C. Albrecht, J. Mol. Spectry., 6, 84 (1961). $^{2}$ Y. N. Chiu, J. Chem. Phys., 46, 772 (1...