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The Effect of SnO2 Mixture on a PVA-Based Thick Film Relative Humidity Sensor

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@article{IJASEIT14869,
   author = {Goib Wiranto and Supeno Martadi and M. Amin Sulthoni and I Dewa Putu Hermida and Yudi Y. Maulana and Slamet Widodo and Deni P. Kurniadi and Pamungkas Daud},
   title = {The Effect of SnO2 Mixture on a PVA-Based Thick Film Relative Humidity Sensor},
   journal = {International Journal on Advanced Science, Engineering and Information Technology},
   volume = {12},
   number = {3},
   year = {2022},
   pages = {1060--1065},
   keywords = {Relative humidity sensor; thick film technology; screen printing; spin coating; PVA; SnO2.},
   abstract = {In this research, thick film technology has been used to design and fabricate relative humidity sensors with Polyvinyl Alcohol (PVA) as the sensing layer. The design was optimized to produce an ideal geometry according to the limitations of thick film technology. The sensor fabrication process used screen printing techniques on Alumina (Al2O3) substrate with Silver (Ag) as the electrode material. SnO2 was added to the PVA sensing layer with variations in the composition of 1:1 and 1:2. FTIR analysis showed that the addition of SnO2 did not affect the structure of the PVA, which indicated that there was no chemical reaction between PVA and SnO2. The deposition of the sensing layer was carried out using spin coating method, and the fabricated sensors were then tested by varying 5 humidity points inside a chamber with a hygrometer as a reference. Based on the test results, it was found that the sensors showed responses to humidity variation in the form of changes in resistance values. When the humidity in the chamber increased, the sensor resistance value decreased. The addition of SnO2 could reduce the relatively high resistance value of the PVA-based humidity sensor and also increase the sensor's time response to humidity variation. However, the humidity sensor’s sensitivity decreased for the higher composition of SnO2. With this technique, a simple yet stable humidity sensor could be fabricated using thick-film technology with a wide range of potential applications.},
   issn = {2088-5334},
   publisher = {INSIGHT - Indonesian Society for Knowledge and Human Development},
   url = {http://ijaseit.insightsociety.org/index.php?option=com_content&view=article&id=9&Itemid=1&article_id=14869},
   doi = {10.18517/ijaseit.12.3.14869}
}

EndNote

%A Wiranto, Goib
%A Martadi, Supeno
%A Sulthoni, M. Amin
%A Hermida, I Dewa Putu
%A Maulana, Yudi Y.
%A Widodo, Slamet
%A Kurniadi, Deni P.
%A Daud, Pamungkas
%D 2022
%T The Effect of SnO2 Mixture on a PVA-Based Thick Film Relative Humidity Sensor
%B 2022
%9 Relative humidity sensor; thick film technology; screen printing; spin coating; PVA; SnO2.
%! The Effect of SnO2 Mixture on a PVA-Based Thick Film Relative Humidity Sensor
%K Relative humidity sensor; thick film technology; screen printing; spin coating; PVA; SnO2.
%X In this research, thick film technology has been used to design and fabricate relative humidity sensors with Polyvinyl Alcohol (PVA) as the sensing layer. The design was optimized to produce an ideal geometry according to the limitations of thick film technology. The sensor fabrication process used screen printing techniques on Alumina (Al2O3) substrate with Silver (Ag) as the electrode material. SnO2 was added to the PVA sensing layer with variations in the composition of 1:1 and 1:2. FTIR analysis showed that the addition of SnO2 did not affect the structure of the PVA, which indicated that there was no chemical reaction between PVA and SnO2. The deposition of the sensing layer was carried out using spin coating method, and the fabricated sensors were then tested by varying 5 humidity points inside a chamber with a hygrometer as a reference. Based on the test results, it was found that the sensors showed responses to humidity variation in the form of changes in resistance values. When the humidity in the chamber increased, the sensor resistance value decreased. The addition of SnO2 could reduce the relatively high resistance value of the PVA-based humidity sensor and also increase the sensor's time response to humidity variation. However, the humidity sensor’s sensitivity decreased for the higher composition of SnO2. With this technique, a simple yet stable humidity sensor could be fabricated using thick-film technology with a wide range of potential applications.
%U http://ijaseit.insightsociety.org/index.php?option=com_content&view=article&id=9&Itemid=1&article_id=14869
%R doi:10.18517/ijaseit.12.3.14869
%J International Journal on Advanced Science, Engineering and Information Technology
%V 12
%N 3
%@ 2088-5334

IEEE

Goib Wiranto,Supeno Martadi,M. Amin Sulthoni,I Dewa Putu Hermida,Yudi Y. Maulana,Slamet Widodo,Deni P. Kurniadi and Pamungkas Daud,"The Effect of SnO2 Mixture on a PVA-Based Thick Film Relative Humidity Sensor," International Journal on Advanced Science, Engineering and Information Technology, vol. 12, no. 3, pp. 1060-1065, 2022. [Online]. Available: http://dx.doi.org/10.18517/ijaseit.12.3.14869.

RefMan/ProCite (RIS)

TY  - JOUR
AU  - Wiranto, Goib
AU  - Martadi, Supeno
AU  - Sulthoni, M. Amin
AU  - Hermida, I Dewa Putu
AU  - Maulana, Yudi Y.
AU  - Widodo, Slamet
AU  - Kurniadi, Deni P.
AU  - Daud, Pamungkas
PY  - 2022
TI  - The Effect of SnO2 Mixture on a PVA-Based Thick Film Relative Humidity Sensor
JF  - International Journal on Advanced Science, Engineering and Information Technology; Vol. 12 (2022) No. 3
Y2  - 2022
SP  - 1060
EP  - 1065
SN  - 2088-5334
PB  - INSIGHT - Indonesian Society for Knowledge and Human Development
KW  - Relative humidity sensor; thick film technology; screen printing; spin coating; PVA; SnO2.
N2  - In this research, thick film technology has been used to design and fabricate relative humidity sensors with Polyvinyl Alcohol (PVA) as the sensing layer. The design was optimized to produce an ideal geometry according to the limitations of thick film technology. The sensor fabrication process used screen printing techniques on Alumina (Al2O3) substrate with Silver (Ag) as the electrode material. SnO2 was added to the PVA sensing layer with variations in the composition of 1:1 and 1:2. FTIR analysis showed that the addition of SnO2 did not affect the structure of the PVA, which indicated that there was no chemical reaction between PVA and SnO2. The deposition of the sensing layer was carried out using spin coating method, and the fabricated sensors were then tested by varying 5 humidity points inside a chamber with a hygrometer as a reference. Based on the test results, it was found that the sensors showed responses to humidity variation in the form of changes in resistance values. When the humidity in the chamber increased, the sensor resistance value decreased. The addition of SnO2 could reduce the relatively high resistance value of the PVA-based humidity sensor and also increase the sensor's time response to humidity variation. However, the humidity sensor’s sensitivity decreased for the higher composition of SnO2. With this technique, a simple yet stable humidity sensor could be fabricated using thick-film technology with a wide range of potential applications.
UR  - http://ijaseit.insightsociety.org/index.php?option=com_content&view=article&id=9&Itemid=1&article_id=14869
DO  - 10.18517/ijaseit.12.3.14869

RefWorks

RT Journal Article
ID 14869
A1 Wiranto, Goib
A1 Martadi, Supeno
A1 Sulthoni, M. Amin
A1 Hermida, I Dewa Putu
A1 Maulana, Yudi Y.
A1 Widodo, Slamet
A1 Kurniadi, Deni P.
A1 Daud, Pamungkas
T1 The Effect of SnO2 Mixture on a PVA-Based Thick Film Relative Humidity Sensor
JF International Journal on Advanced Science, Engineering and Information Technology
VO 12
IS 3
YR 2022
SP 1060
OP 1065
SN 2088-5334
PB INSIGHT - Indonesian Society for Knowledge and Human Development
K1 Relative humidity sensor; thick film technology; screen printing; spin coating; PVA; SnO2.
AB In this research, thick film technology has been used to design and fabricate relative humidity sensors with Polyvinyl Alcohol (PVA) as the sensing layer. The design was optimized to produce an ideal geometry according to the limitations of thick film technology. The sensor fabrication process used screen printing techniques on Alumina (Al2O3) substrate with Silver (Ag) as the electrode material. SnO2 was added to the PVA sensing layer with variations in the composition of 1:1 and 1:2. FTIR analysis showed that the addition of SnO2 did not affect the structure of the PVA, which indicated that there was no chemical reaction between PVA and SnO2. The deposition of the sensing layer was carried out using spin coating method, and the fabricated sensors were then tested by varying 5 humidity points inside a chamber with a hygrometer as a reference. Based on the test results, it was found that the sensors showed responses to humidity variation in the form of changes in resistance values. When the humidity in the chamber increased, the sensor resistance value decreased. The addition of SnO2 could reduce the relatively high resistance value of the PVA-based humidity sensor and also increase the sensor's time response to humidity variation. However, the humidity sensor’s sensitivity decreased for the higher composition of SnO2. With this technique, a simple yet stable humidity sensor could be fabricated using thick-film technology with a wide range of potential applications.
LK http://ijaseit.insightsociety.org/index.php?option=com_content&view=article&id=9&Itemid=1&article_id=14869
DO  - 10.18517/ijaseit.12.3.14869