Azimuthal polarization filtering for accurate, precise, and robust single-molecule localization microscopy

Matthew D. Lew; W. E. Moerner

doi:10.1021/nl502914k

Azimuthal polarization filtering for accurate, precise, and robust single-molecule localization microscopy

Matthew D. Lew, W. E. Moerner

Research output: Contribution to journal › Article › peer-review

54 Scopus citations

Abstract

Many single nanoemitters such as fluorescent molecules produce dipole radiation that leads to systematic position errors in both particle tracking and super-resolution microscopy. Via vectorial diffraction equations and simulations, we show that imaging only azimuthally polarized light in the microscope naturally avoids emission from the z-component of the transition dipole moment, resulting in negligible localization errors for all emitter orientations and degrees of objective lens misfocus. Furthermore, localization accuracy is maintained even in the presence of aberrations resulting from imaging in mismatched media.

Original language	English
Pages (from-to)	6407-6413
Number of pages	7
Journal	Nano Letters
Volume	14
Issue number	11
DOIs	https://doi.org/10.1021/nl502914k
State	Published - Nov 12 2014

Keywords

Dipole emission pattern
fluorescence
localization error
molecular orientation
single-molecule imaging
super-resolution microscopy

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10.1021/nl502914k

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abstract = "Many single nanoemitters such as fluorescent molecules produce dipole radiation that leads to systematic position errors in both particle tracking and super-resolution microscopy. Via vectorial diffraction equations and simulations, we show that imaging only azimuthally polarized light in the microscope naturally avoids emission from the z-component of the transition dipole moment, resulting in negligible localization errors for all emitter orientations and degrees of objective lens misfocus. Furthermore, localization accuracy is maintained even in the presence of aberrations resulting from imaging in mismatched media.",

keywords = "Dipole emission pattern, fluorescence, localization error, molecular orientation, single-molecule imaging, super-resolution microscopy",

author = "Lew, {Matthew D.} and Moerner, {W. E.}",

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AU - Moerner, W. E.

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N2 - Many single nanoemitters such as fluorescent molecules produce dipole radiation that leads to systematic position errors in both particle tracking and super-resolution microscopy. Via vectorial diffraction equations and simulations, we show that imaging only azimuthally polarized light in the microscope naturally avoids emission from the z-component of the transition dipole moment, resulting in negligible localization errors for all emitter orientations and degrees of objective lens misfocus. Furthermore, localization accuracy is maintained even in the presence of aberrations resulting from imaging in mismatched media.

AB - Many single nanoemitters such as fluorescent molecules produce dipole radiation that leads to systematic position errors in both particle tracking and super-resolution microscopy. Via vectorial diffraction equations and simulations, we show that imaging only azimuthally polarized light in the microscope naturally avoids emission from the z-component of the transition dipole moment, resulting in negligible localization errors for all emitter orientations and degrees of objective lens misfocus. Furthermore, localization accuracy is maintained even in the presence of aberrations resulting from imaging in mismatched media.

KW - Dipole emission pattern

KW - fluorescence

KW - localization error

KW - molecular orientation

KW - single-molecule imaging

KW - super-resolution microscopy

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JO - Nano Letters

JF - Nano Letters

IS - 11

ER -

Azimuthal polarization filtering for accurate, precise, and robust single-molecule localization microscopy

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Keywords

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