High-Resolution Photonic Force Microscopy Based on Sharp Nanofabricated Tips

Overview

Journal Nano Lett

Publisher American Chemical Society

Specialty Biotechnology

Date 2020 May 6

PMID 32369369

Citations 3

Authors

Rudy Desgarceaux

Zhanna Santybayeva

Eliana Battistella

Ashley L Nord

Catherine Braun-Breton

Manouk Abkarian

Onofrio M Marago

Benoit Charlot

Francesco Pedaci

Affiliations

Soon will be listed here.

Abstract

Although near-field imaging techniques reach sub-nanometer resolution on rigid samples, it remains extremely challenging to image soft interfaces, such as biological membranes, due to the deformations induced by the probe. In photonic force microscopy, optical tweezers are used to manipulate and measure the scanning probe, allowing imaging of soft materials without force-induced artifacts. However, the size of the optically trapped probe still limits the maximum resolution. Here, we show a novel and simple nanofabrication protocol to massively produce optically trappable quartz particles which mimic the sharp tips of atomic force microscopy. Imaging rigid nanostructures with our tips, we resolve features smaller than 80 nm. Scanning the membrane of living malaria-infected red blood cells reveals, with no visible artifacts, submicron features termed knobs, related to the parasite activity. The use of nanoengineered particles in photonic force microscopy opens the way to imaging soft samples at high resolution.

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