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Permittivity measurements up to 30 GHz using micromachined probe

Permittivity measurements up to 30 GHz using micromachined probe

Authors :
Youngwoo Kwon
Changyul Cheon
Dong Hoon Oh
Jae-Hyoung Park
Yong-Kweon Kim
Jeiwon Cho
Jung Mu Kim
Source :
Journal of Micromechanics and Microengineering. 15:543-550
Publication Year :
2004
Publisher :
IOP Publishing, 2004.

Abstract

We implemented a micromachined probe for the measurement of biological properties using MEMS technology, and experimentally showed the suitability of the micromachined probe in biological applications. The micromachined probe was fabricated on a silicon substrate, and to remove wave transmission through the silicon substrate, we etched the silicon substrate from beneath a lower ground and made the etched silicon surface conducting by using thermal evaporation of Cr/Au and a coating of conductive epoxy. The micromachined probe consists of a CPW and strip line between benzo cyclo butene (BCB) layers, which is known to be a material with high resistivity, low loss tangent, and low permittivity at high frequency. We measured the permittivity of a number of well-known liquids—0.5%, 0.9% and 1.3% saline, acetone, ethanol, and muscle and fat of pork—as biological samples using the micromachined probe after liquid calibration. The measured permittivity of 0.9% saline agreed well with the expected value of the Cole–Cole equation. In this paper, we first demonstrate that the micromachined probe can provide broadband measurement of measurable solid materials, such as biological samples, and also of well-known liquids at microwave frequencies. The size of the micromachined probe is 2000 µm (width) × 580 µm (thickness) × 30 000 µm (length), and the aperture size of the micromachined probe is only 650 µm × 70 µm. Therefore, we can extract the biological information from very small biological tissues and reduce radiation effects. Thus we show the feasibility of low-cost, small and portable permittivity measurement systems using a micromachined open-ended coaxial RF MEMS probe.

Details

ISSN :
13616439 and 09601317
Volume :
15
Database :
OpenAIRE
Journal :
Journal of Micromechanics and Microengineering
Accession number :
edsair.doi...........97b2cd077bbdab4bc985a78d1a8ede0e
Full Text :
https://doi.org/10.1088/0960-1317/15/3/015