Measurement of microchannel fluidic resistance with a standard voltage meter
| Autor: | Louis A. Jackson, Leah A. Godwin, Lauren D. Hoepfner, Kennon S. Deal, Christopher J. Easley |
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| Rok vydání: | 2012 |
| Předmět: |
Microchannel
Chemistry Acoustics Electrical Equipment and Supplies Microfluidics Analytical chemistry Equipment Design Standard solution Microfluidic Analytical Techniques Biochemistry Article Analytical Chemistry law.invention Solutions Electrical resistance and conductance Voltmeter law Calibration Electric Impedance Environmental Chemistry Fluidics Resistor Spectroscopy |
| Zdroj: | Analytica chimica acta. 758 |
| ISSN: | 1873-4324 |
| Popis: | A simplified method for measuring the fluidic resistance (R(fluidic)) of microfluidic channels is presented, in which the electrical resistance (R(elec)) of a channel filled with a conductivity standard solution can be measured and directly correlated to R(fluidic) using a simple equation. Although a slight correction factor could be applied in this system to improve accuracy, results showed that a standard voltage meter could be used without calibration to determine R(fluidic) to within 12% error. Results accurate to within 2% were obtained when a geometric correction factor was applied using these particular channels. When compared to standard flow rate measurements, such as meniscus tracking in outlet tubing, this approach provided a more straightforward alternative and resulted in lower measurement error. The method was validated using 9 different fluidic resistance values (from ∼40 to 600kPa smm(-3)) and over 30 separately fabricated microfluidic devices. Furthermore, since the method is analogous to resistance measurements with a voltage meter in electrical circuits, dynamic R(fluidic) measurements were possible in more complex microfluidic designs. Microchannel R(elec) was shown to dynamically mimic pressure waveforms applied to a membrane in a variable microfluidic resistor. The variable resistor was then used to dynamically control aqueous-in-oil droplet sizes and spacing, providing a unique and convenient control system for droplet-generating devices. This conductivity-based method for fluidic resistance measurement is thus a useful tool for static or real-time characterization of microfluidic systems. |
| Databáze: | OpenAIRE |
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