Radio Frequency Detection and Characterization of Water-Ethanol Solution through Spiral-Coupled Passive Micro-Resonator Sensor

Radio Frequency Detection and Characterization of Water-Ethanol Solution through Spiral-Coupled Passive Micro-Resonator Sensor

We present a microfabricated spiral-coupled passive resonator sensor realized through integrated passive device (IPD) technology for the sensitive detection and characterization of water-ethanol solutions. In order to validate the performance of the proposed device, we explicitly measured and analyz...

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Main Authors: Gyan Raj Koirala, Rajendra Dhakal, Eun-Seong Kim, Zhao Yao, Nam-Young Kim
Format: Article
Language:English
Published: MDPI AG 2018-04-01
Series:Sensors
Subjects:
micro-resonator sensor
permittivity
radio frequency
reproducible
water-ethanol
Online Access:http://www.mdpi.com/1424-8220/18/4/1075
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record_format Article
spelling doaj-91c4bbc2b79649bd805bd3c102d06cd82020-11-24T22:22:24ZengMDPI AGSensors1424-82202018-04-01184107510.3390/s18041075s18041075Radio Frequency Detection and Characterization of Water-Ethanol Solution through Spiral-Coupled Passive Micro-Resonator SensorGyan Raj Koirala0Rajendra Dhakal1Eun-Seong Kim2Zhao Yao3Nam-Young Kim4RFIC Lab, Department of Electronic Engineering, Kwangwoon University, 01897 Seoul, KoreaRFIC Lab, Department of Electronic Engineering, Kwangwoon University, 01897 Seoul, KoreaRFIC Lab, Department of Electronic Engineering, Kwangwoon University, 01897 Seoul, KoreaRFIC Lab, Department of Electronic Engineering, Kwangwoon University, 01897 Seoul, KoreaRFIC Lab, Department of Electronic Engineering, Kwangwoon University, 01897 Seoul, KoreaWe present a microfabricated spiral-coupled passive resonator sensor realized through integrated passive device (IPD) technology for the sensitive detection and characterization of water-ethanol solutions. In order to validate the performance of the proposed device, we explicitly measured and analyzed the radio frequency (RF) characteristics of various water-ethanol solution compositions. The measured results showed a drift in the resonance frequency from 1.16 GHz for deionized (DI) water to 1.68 GHz for the solution containing 50% ethanol, whereas the rejection level given by the reflection coefficient decreased from −29.74 dB to −14.81 dB. The obtained limit of detection was 3.82% volume composition of ethanol in solution. The derived loaded capacitance was 21.76 pF for DI water, which gradually decreased to 8.70 pF for the 50% ethanol solution, and the corresponding relative permittivity of the solution decreased from 80.14 to 47.79. The dissipation factor increased with the concentration of ethanol in the solution. We demonstrated the reproducibility of the proposed sensor through iterative measures of the samples and the study of surface morphology. Successive measurement of different samples had no overlapping and had very minimum bias between RF characteristics for each measured sample. The surface profile for bare sensors was retained after the sample test, resulting a root mean square (RMS) value of 11.416 nm as compared to 10.902 nm for the bare test. The proposed sensor was shown to be a viable alternative to existing sensors for highly sensitive water-ethanol concentration detection.http://www.mdpi.com/1424-8220/18/4/1075micro-resonator sensorpermittivityradio frequencyreproduciblewater-ethanol
collection DOAJ
language English
format Article
sources DOAJ
author Gyan Raj Koirala
Rajendra Dhakal
Eun-Seong Kim
Zhao Yao
Nam-Young Kim
spellingShingle Gyan Raj Koirala
Rajendra Dhakal
Eun-Seong Kim
Zhao Yao
Nam-Young Kim
Radio Frequency Detection and Characterization of Water-Ethanol Solution through Spiral-Coupled Passive Micro-Resonator Sensor
Sensors
micro-resonator sensor
permittivity
radio frequency
reproducible
water-ethanol
author_facet Gyan Raj Koirala
Rajendra Dhakal
Eun-Seong Kim
Zhao Yao
Nam-Young Kim
author_sort Gyan Raj Koirala
title Radio Frequency Detection and Characterization of Water-Ethanol Solution through Spiral-Coupled Passive Micro-Resonator Sensor
title_short Radio Frequency Detection and Characterization of Water-Ethanol Solution through Spiral-Coupled Passive Micro-Resonator Sensor
title_full Radio Frequency Detection and Characterization of Water-Ethanol Solution through Spiral-Coupled Passive Micro-Resonator Sensor
title_fullStr Radio Frequency Detection and Characterization of Water-Ethanol Solution through Spiral-Coupled Passive Micro-Resonator Sensor
title_full_unstemmed Radio Frequency Detection and Characterization of Water-Ethanol Solution through Spiral-Coupled Passive Micro-Resonator Sensor
title_sort radio frequency detection and characterization of water-ethanol solution through spiral-coupled passive micro-resonator sensor
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2018-04-01
description We present a microfabricated spiral-coupled passive resonator sensor realized through integrated passive device (IPD) technology for the sensitive detection and characterization of water-ethanol solutions. In order to validate the performance of the proposed device, we explicitly measured and analyzed the radio frequency (RF) characteristics of various water-ethanol solution compositions. The measured results showed a drift in the resonance frequency from 1.16 GHz for deionized (DI) water to 1.68 GHz for the solution containing 50% ethanol, whereas the rejection level given by the reflection coefficient decreased from −29.74 dB to −14.81 dB. The obtained limit of detection was 3.82% volume composition of ethanol in solution. The derived loaded capacitance was 21.76 pF for DI water, which gradually decreased to 8.70 pF for the 50% ethanol solution, and the corresponding relative permittivity of the solution decreased from 80.14 to 47.79. The dissipation factor increased with the concentration of ethanol in the solution. We demonstrated the reproducibility of the proposed sensor through iterative measures of the samples and the study of surface morphology. Successive measurement of different samples had no overlapping and had very minimum bias between RF characteristics for each measured sample. The surface profile for bare sensors was retained after the sample test, resulting a root mean square (RMS) value of 11.416 nm as compared to 10.902 nm for the bare test. The proposed sensor was shown to be a viable alternative to existing sensors for highly sensitive water-ethanol concentration detection.
topic micro-resonator sensor
permittivity
radio frequency
reproducible
water-ethanol
url http://www.mdpi.com/1424-8220/18/4/1075
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AT rajendradhakal radiofrequencydetectionandcharacterizationofwaterethanolsolutionthroughspiralcoupledpassivemicroresonatorsensor
AT eunseongkim radiofrequencydetectionandcharacterizationofwaterethanolsolutionthroughspiralcoupledpassivemicroresonatorsensor
AT zhaoyao radiofrequencydetectionandcharacterizationofwaterethanolsolutionthroughspiralcoupledpassivemicroresonatorsensor
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