Scaling of interface displacement in a microfluidic comparator

Srinivas Vanapalli; V.S.A.R. Vanapalli Veera; Henricus T.M. van den Ende; Michael H.G. Duits; Friedrich Gunther Mugele

doi:10.1063/1.2713800

Scaling of interface displacement in a microfluidic comparator

Srinivas Vanapalli, V.S.A.R. Vanapalli Veera, Henricus T.M. van den Ende, Michael H.G. Duits, Friedrich Gunther Mugele

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

22 Citations (Scopus)

Abstract

The authors quantify both experimentally and theoretically the scaling behavior between interface displacement and excess pressure drop in a microfluidic comparator. Unlike previous studies, the authors measure the interface displacement in the outlet channel of the comparator that yields a unique power-law scaling. For an outlet channel width to depth ratio r=3, the authors experimentally determine the scaling exponent to be 0.60±0.01, which is in excellent agreement with theory. In general, the authors find the scaling exponent to increase from 0.51 for square channels (r=1) to 0.93 for very wide channels (r>100). This geometry dependent scaling exponent offers greater sensitivity and flexibility in measurement of hydrodynamic resistance of soft objects

Original language	Undefined
Pages (from-to)	114109-
Journal	Applied physics letters
Volume	90
Issue number	11
DOIs	https://doi.org/10.1063/1.2713800
Publication status	Published - 2007

Keywords

METIS-240111
IR-57947

Access to Document

10.1063/1.2713800

Cite this

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title = "Scaling of interface displacement in a microfluidic comparator",

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AU - Vanapalli, Srinivas

AU - Vanapalli Veera, V.S.A.R.

AU - van den Ende, Henricus T.M.

AU - Duits, Michael H.G.

AU - Mugele, Friedrich Gunther

PY - 2007

Y1 - 2007

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AB - The authors quantify both experimentally and theoretically the scaling behavior between interface displacement and excess pressure drop in a microfluidic comparator. Unlike previous studies, the authors measure the interface displacement in the outlet channel of the comparator that yields a unique power-law scaling. For an outlet channel width to depth ratio r=3, the authors experimentally determine the scaling exponent to be 0.60±0.01, which is in excellent agreement with theory. In general, the authors find the scaling exponent to increase from 0.51 for square channels (r=1) to 0.93 for very wide channels (r>100). This geometry dependent scaling exponent offers greater sensitivity and flexibility in measurement of hydrodynamic resistance of soft objects

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