Data provided by National Institute of Standards and Technology
Abstract from manuscript:We demonstrate a glass microwave microfluidic device for determining the permittivity of a wide range of liquid chemicals from 100 MHz to 10 GHz with relatively low uncertainty. Conventional microwave microfluidic devices use polymer-based microfluidic layers for fluid delivery, but these polymers swell in organic solvents and are not suitable for many applications. Our device incorporates glass microfluidic channels with platinum coplanar waveguides to provide a solvent-resistant architecture for broadband dielectric spectroscopy of fluids. We utilize broadband S-parameter measurements with a vector network analyzer on a wafer probing station and multiline thru-reflect-line calibrations to extract the distributed circuit parameters of transmission lines and solve for fluid permittivity. In this work, we demonstrate the utility of the device by measuring the broadband permittivity of four organic solvents difficult to measure otherwise: hexane, heptane, decane, and toluene.
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Updated: 2025-04-06
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2024-06-10 00:00:00
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| Title | Data associated with the manuscript "Glass microwave microfluidic devices for broadband characterization of diverse fluids" submitted to the Special Issue of the International Microwave Symposium (IMS) 2024 of IEEE Transactions of Microwave Theory and Techniques. |
|---|---|
| Description | Abstract from manuscript:We demonstrate a glass microwave microfluidic device for determining the permittivity of a wide range of liquid chemicals from 100 MHz to 10 GHz with relatively low uncertainty. Conventional microwave microfluidic devices use polymer-based microfluidic layers for fluid delivery, but these polymers swell in organic solvents and are not suitable for many applications. Our device incorporates glass microfluidic channels with platinum coplanar waveguides to provide a solvent-resistant architecture for broadband dielectric spectroscopy of fluids. We utilize broadband S-parameter measurements with a vector network analyzer on a wafer probing station and multiline thru-reflect-line calibrations to extract the distributed circuit parameters of transmission lines and solve for fluid permittivity. In this work, we demonstrate the utility of the device by measuring the broadband permittivity of four organic solvents difficult to measure otherwise: hexane, heptane, decane, and toluene. |
| Modified | 2024-06-10 00:00:00 |
| Publisher Name | National Institute of Standards and Technology |
| Contact | mailto:[email protected] |
| Keywords | Glass microfluidics , microwave devices , dielectric spectroscopy , permittivity |
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"title": "Data associated with the manuscript \"Glass microwave microfluidic devices for broadband characterization of diverse fluids\" submitted to the Special Issue of the International Microwave Symposium (IMS) 2024 of IEEE Transactions of Microwave Theory and Techniques.",
"description": "Abstract from manuscript:We demonstrate a glass microwave microfluidic device for determining the permittivity of a wide range of liquid chemicals from 100 MHz to 10 GHz with relatively low uncertainty. Conventional microwave microfluidic devices use polymer-based microfluidic layers for fluid delivery, but these polymers swell in organic solvents and are not suitable for many applications. Our device incorporates glass microfluidic channels with platinum coplanar waveguides to provide a solvent-resistant architecture for broadband dielectric spectroscopy of fluids. We utilize broadband S-parameter measurements with a vector network analyzer on a wafer probing station and multiline thru-reflect-line calibrations to extract the distributed circuit parameters of transmission lines and solve for fluid permittivity. In this work, we demonstrate the utility of the device by measuring the broadband permittivity of four organic solvents difficult to measure otherwise: hexane, heptane, decane, and toluene.",
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