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Hauptverfasser: Liu, Yuan, Lo, Jack Hau Yung, Nunes, Janine K., Stone, Howard A., Shum, Ho Cheung
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2403.12225
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author Liu, Yuan
Lo, Jack Hau Yung
Nunes, Janine K.
Stone, Howard A.
Shum, Ho Cheung
author_facet Liu, Yuan
Lo, Jack Hau Yung
Nunes, Janine K.
Stone, Howard A.
Shum, Ho Cheung
contents There are many fields where it is of interest to measure the elastic moduli of tiny fragile fibers, such as filamentous bacteria, actin filaments, DNA, carbon nanotubes, and functional microfibers. The elastic modulus is typically deduced from a sophisticated tensile test under a microscope, but the throughput is low and limited by the time-consuming and skill-intensive sample loading/unloading. Here, we demonstrate a simple microfluidic method enabling the high-throughput measurement of the elastic moduli of microfibers by rope coiling using a localized compression, where sample loading/unloading are not needed between consecutive measurements. The rope coiling phenomenon occurs spontaneously when a microfiber flows from a small channel into a wide channel. The elastic modulus is determined by measuring either the buckling length or the coiling radius. The throughput of this method, currently 3,300 fibers per hour, is a thousand times higher than that of a tensile tester. We demonstrate the feasibility of the method by testing a nonuniform fiber with axially varying elastic modulus. We also demonstrate its capability for in situ inline measurement in a microfluidic production line. We envisage that high-throughput measurements may facilitate potential applications such as screening or sorting by mechanical properties and real-time control during production of microfibers.
format Preprint
id arxiv_https___arxiv_org_abs_2403_12225
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle High-throughput measurement of elastic moduli of microfibers by rope coiling
Liu, Yuan
Lo, Jack Hau Yung
Nunes, Janine K.
Stone, Howard A.
Shum, Ho Cheung
Soft Condensed Matter
There are many fields where it is of interest to measure the elastic moduli of tiny fragile fibers, such as filamentous bacteria, actin filaments, DNA, carbon nanotubes, and functional microfibers. The elastic modulus is typically deduced from a sophisticated tensile test under a microscope, but the throughput is low and limited by the time-consuming and skill-intensive sample loading/unloading. Here, we demonstrate a simple microfluidic method enabling the high-throughput measurement of the elastic moduli of microfibers by rope coiling using a localized compression, where sample loading/unloading are not needed between consecutive measurements. The rope coiling phenomenon occurs spontaneously when a microfiber flows from a small channel into a wide channel. The elastic modulus is determined by measuring either the buckling length or the coiling radius. The throughput of this method, currently 3,300 fibers per hour, is a thousand times higher than that of a tensile tester. We demonstrate the feasibility of the method by testing a nonuniform fiber with axially varying elastic modulus. We also demonstrate its capability for in situ inline measurement in a microfluidic production line. We envisage that high-throughput measurements may facilitate potential applications such as screening or sorting by mechanical properties and real-time control during production of microfibers.
title High-throughput measurement of elastic moduli of microfibers by rope coiling
topic Soft Condensed Matter
url https://arxiv.org/abs/2403.12225