Unified Simulation Platform for Interference Microscopy

Felix Hitzelhammer; Anežka Dostálová; Ilia Zykov; Barbara Platzer; Clara Conrad-Billroth; Thomas Juffmann; Ulrich Hohenester

doi:10.1021/acsphotonics.4c00621

Unified Simulation Platform for Interference Microscopy

Felix Hitzelhammer, Anežka Dostálová, Ilia Zykov, Barbara Platzer, Clara Conrad-Billroth, Thomas Juffmann, Ulrich Hohenester

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

Interferometric scattering microscopy is a powerful technique that enables various applications, such as mass photometry and particle tracking. Here, we present a numerical toolbox to simulate images obtained in interferometric scattering, coherent bright-field, and dark-field microscopies. The scattered fields are calculated using a boundary element method, facilitating the simulation of arbitrary sample geometries and substrate layer structures. A fully vectorial model is used for simulating the imaging setup. We demonstrate excellent agreement between our simulations and experiments for different shapes of scatterers and excitation angles. Notably, for angles near the Brewster angle, we observe a contrast enhancement which may be beneficial for nanosensing applications. The software is available as a matlab toolbox.

Original language	English
Pages (from-to)	2745-2756
Number of pages	12
Journal	ACS Photonics
Volume	11
Issue number	7
DOIs	https://doi.org/10.1021/acsphotonics.4c00621
Publication status	Published - 17 Jul 2024

Austrian Fields of Science 2012

103045 Light optical microscopy

Keywords

coherent bright-field microscopy
interference microscopy
nanosensing
particle tracking
simulation

Access to Document

10.1021/acsphotonics.4c00621

Cite this

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title = "Unified Simulation Platform for Interference Microscopy",

abstract = "Interferometric scattering microscopy is a powerful technique that enables various applications, such as mass photometry and particle tracking. Here, we present a numerical toolbox to simulate images obtained in interferometric scattering, coherent bright-field, and dark-field microscopies. The scattered fields are calculated using a boundary element method, facilitating the simulation of arbitrary sample geometries and substrate layer structures. A fully vectorial model is used for simulating the imaging setup. We demonstrate excellent agreement between our simulations and experiments for different shapes of scatterers and excitation angles. Notably, for angles near the Brewster angle, we observe a contrast enhancement which may be beneficial for nanosensing applications. The software is available as a matlab toolbox.",

keywords = "coherent bright-field microscopy, interference microscopy, nanosensing, particle tracking, simulation",

author = "Felix Hitzelhammer and Ane{\v z}ka Dost{\'a}lov{\'a} and Ilia Zykov and Barbara Platzer and Clara Conrad-Billroth and Thomas Juffmann and Ulrich Hohenester",

note = "Publisher Copyright: {\textcopyright} 2024 The Authors. Published by American Chemical Society.",

year = "2024",

month = jul,

day = "17",

doi = "10.1021/acsphotonics.4c00621",

language = "English",

volume = "11",

pages = "2745--2756",

journal = "ACS Photonics",

issn = "2330-4022",

publisher = "American Chemical Society",

number = "7",

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TY - JOUR

T1 - Unified Simulation Platform for Interference Microscopy

AU - Hitzelhammer, Felix

AU - Dostálová, Anežka

AU - Zykov, Ilia

AU - Platzer, Barbara

AU - Conrad-Billroth, Clara

AU - Juffmann, Thomas

AU - Hohenester, Ulrich

PY - 2024/7/17

Y1 - 2024/7/17

N2 - Interferometric scattering microscopy is a powerful technique that enables various applications, such as mass photometry and particle tracking. Here, we present a numerical toolbox to simulate images obtained in interferometric scattering, coherent bright-field, and dark-field microscopies. The scattered fields are calculated using a boundary element method, facilitating the simulation of arbitrary sample geometries and substrate layer structures. A fully vectorial model is used for simulating the imaging setup. We demonstrate excellent agreement between our simulations and experiments for different shapes of scatterers and excitation angles. Notably, for angles near the Brewster angle, we observe a contrast enhancement which may be beneficial for nanosensing applications. The software is available as a matlab toolbox.

AB - Interferometric scattering microscopy is a powerful technique that enables various applications, such as mass photometry and particle tracking. Here, we present a numerical toolbox to simulate images obtained in interferometric scattering, coherent bright-field, and dark-field microscopies. The scattered fields are calculated using a boundary element method, facilitating the simulation of arbitrary sample geometries and substrate layer structures. A fully vectorial model is used for simulating the imaging setup. We demonstrate excellent agreement between our simulations and experiments for different shapes of scatterers and excitation angles. Notably, for angles near the Brewster angle, we observe a contrast enhancement which may be beneficial for nanosensing applications. The software is available as a matlab toolbox.

KW - coherent bright-field microscopy

KW - interference microscopy

KW - nanosensing

KW - particle tracking

KW - simulation

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U2 - 10.1021/acsphotonics.4c00621

DO - 10.1021/acsphotonics.4c00621

M3 - Article

AN - SCOPUS:85196761720

SN - 2330-4022

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SP - 2745

EP - 2756

JO - ACS Photonics

JF - ACS Photonics

IS - 7

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Unified Simulation Platform for Interference Microscopy

Abstract

Austrian Fields of Science 2012

Keywords

Access to Document

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Fingerprint

ONEM: Optical Near-field Electron Microscopy

MicroMOUPE: Microscopy - Making optimal use of photons and electrons

Cite this

Unified Simulation Platform for Interference Microscopy

Abstract

Austrian Fields of Science 2012

Keywords

Access to Document

Other files and links

Fingerprint

Projects

ONEM: Optical Near-field Electron Microscopy

MicroMOUPE: Microscopy - Making optimal use of photons and electrons

Cite this