TY - JOUR
T1 - A colour-encoded nanometric ruler for axial super-resolution microscopies
AU - Olevsko, Ilya
AU - Shavit, Omer
AU - Feldberg, Moshe
AU - Abulafia, Yossi
AU - Salomon, Adi
AU - Oheim, Martin
N1 - Publisher Copyright:
© 2024
PY - 2024/8/15
Y1 - 2024/8/15
N2 - Recent progress has boosted the resolving power of optical microscopies to spatial dimensions well below the diffraction limit. Yet, axial super-resolution and axial single-molecule localisation typically require more complicated implementations than their lateral counterparts. Also, comparison between techniques remains a major challenge due to the absence of suitable calibration tools that would permit a metrology along the microscope's optical axis. Likewise, such test samples would be useful as well for quantifying nanometric drift, or axial fluorophore mobility, or again for quantifying the sub-wavelength light confinement in near-field microscopies. In the present work, we propose a colour-encoded nanoscopic axial ruler. We provide a multi-layered single-excitation, dual-emission test slide, which translates the axial-distance problem into a spectral measurement. Our test slide combines, on a standard microscope coverslip substrate, two flat, thin, uniform and brightly emitting fluorophore layers, separated by a nanometric transparent spacer layer having a refractive index close to a biological cell. The ensemble is sealed in an index-matched protective polymer. As a proof-of-principle, we demonstrate the light confinement resulting from evanescent-wave excitation in total internal reflection fluorescence (TIRF) microscopy. Our test sample permits, even for the non-expert user, a facile axial metrology at the sub-100-nm scale, a critical requirement for axial super-resolution, as well as near-surface imaging, spectroscopy and sensing. (201 words).
AB - Recent progress has boosted the resolving power of optical microscopies to spatial dimensions well below the diffraction limit. Yet, axial super-resolution and axial single-molecule localisation typically require more complicated implementations than their lateral counterparts. Also, comparison between techniques remains a major challenge due to the absence of suitable calibration tools that would permit a metrology along the microscope's optical axis. Likewise, such test samples would be useful as well for quantifying nanometric drift, or axial fluorophore mobility, or again for quantifying the sub-wavelength light confinement in near-field microscopies. In the present work, we propose a colour-encoded nanoscopic axial ruler. We provide a multi-layered single-excitation, dual-emission test slide, which translates the axial-distance problem into a spectral measurement. Our test slide combines, on a standard microscope coverslip substrate, two flat, thin, uniform and brightly emitting fluorophore layers, separated by a nanometric transparent spacer layer having a refractive index close to a biological cell. The ensemble is sealed in an index-matched protective polymer. As a proof-of-principle, we demonstrate the light confinement resulting from evanescent-wave excitation in total internal reflection fluorescence (TIRF) microscopy. Our test sample permits, even for the non-expert user, a facile axial metrology at the sub-100-nm scale, a critical requirement for axial super-resolution, as well as near-surface imaging, spectroscopy and sensing. (201 words).
KW - Evanescent-field
KW - fluorescence microscopy
KW - Nanocharacterization
KW - Nanofabrication
KW - Spectoscopy
KW - TIRF
UR - http://www.scopus.com/inward/record.url?scp=85192961434&partnerID=8YFLogxK
U2 - 10.1016/j.optcom.2024.130538
DO - 10.1016/j.optcom.2024.130538
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AN - SCOPUS:85192961434
SN - 0030-4018
VL - 565
JO - Optics Communications
JF - Optics Communications
M1 - 130538
ER -