Electrical properties of screen printed PZT thick films infiltrated with photo-sensitive sol compared with normal sol for cantilever type biochip

Jae Hong Park, Jin Ho Son, Dae Sung Yoon, Tae Song Kim, Hyung-Ho Park, Hwan Kim

Research output: Contribution to journalConference article

7 Citations (Scopus)

Abstract

Much attention has been paid to PZT thick films on Si-based substrate since they began to be used as piezoelectric actuators and sensors with introduction of MEMS technology and screen printing method. However, the thick films made just by screen printing method have high porosity as compared with bulk product, and the PZT thick films on Si-based substrate have problems regarding degradation of active materials and interface properties owing to inter-diffusion or reaction between Si substrate and PZT materials at high temperature for sintering. Thus we have fabricated screen printed PZT thick films on Si substrate using screen printing method and sol infiltration forenhancing densification. New ethanol based photo-sensitive (self-pattem-able) sol and conventional diol based sol were used in order to compare influence of patterning process and investigate adoptability in device process for biochip. Thick films with relative high densities at low temperature, 800°C and without inter-diffusion and reaction between the layers and thick film were accomplished. And it was revealed that the PZT thick film treated by ethanol based self pattern-able sol showed better electrical properties as well as better pattern-ability, and consequently it was applicable to cantilever based biochip without additional PZT film patterning process.

Original languageEnglish
Pages (from-to)163-171
Number of pages9
JournalIntegrated Ferroelectrics
Volume69
DOIs
Publication statusPublished - 2005 Dec 1
Event16th International Symposium on Integrated Ferroelectrics, ISIF-16 - Gyeongju, Korea, Republic of
Duration: 2004 Apr 52004 Apr 8

Fingerprint

Biochips
Polymethyl Methacrylate
Sols
Thick films
thick films
Electric properties
electrical properties
Screen printing
printing
Substrates
Ethanol
ethyl alcohol
Interdiffusion (solids)
piezoelectric actuators
Piezoelectric actuators
infiltration
densification
Densification
Infiltration
microelectromechanical systems

All Science Journal Classification (ASJC) codes

  • Electronic, Optical and Magnetic Materials
  • Control and Systems Engineering
  • Ceramics and Composites
  • Condensed Matter Physics
  • Electrical and Electronic Engineering
  • Materials Chemistry

Cite this

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title = "Electrical properties of screen printed PZT thick films infiltrated with photo-sensitive sol compared with normal sol for cantilever type biochip",
abstract = "Much attention has been paid to PZT thick films on Si-based substrate since they began to be used as piezoelectric actuators and sensors with introduction of MEMS technology and screen printing method. However, the thick films made just by screen printing method have high porosity as compared with bulk product, and the PZT thick films on Si-based substrate have problems regarding degradation of active materials and interface properties owing to inter-diffusion or reaction between Si substrate and PZT materials at high temperature for sintering. Thus we have fabricated screen printed PZT thick films on Si substrate using screen printing method and sol infiltration forenhancing densification. New ethanol based photo-sensitive (self-pattem-able) sol and conventional diol based sol were used in order to compare influence of patterning process and investigate adoptability in device process for biochip. Thick films with relative high densities at low temperature, 800°C and without inter-diffusion and reaction between the layers and thick film were accomplished. And it was revealed that the PZT thick film treated by ethanol based self pattern-able sol showed better electrical properties as well as better pattern-ability, and consequently it was applicable to cantilever based biochip without additional PZT film patterning process.",
author = "Park, {Jae Hong} and Son, {Jin Ho} and Yoon, {Dae Sung} and Kim, {Tae Song} and Hyung-Ho Park and Hwan Kim",
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Electrical properties of screen printed PZT thick films infiltrated with photo-sensitive sol compared with normal sol for cantilever type biochip. / Park, Jae Hong; Son, Jin Ho; Yoon, Dae Sung; Kim, Tae Song; Park, Hyung-Ho; Kim, Hwan.

In: Integrated Ferroelectrics, Vol. 69, 01.12.2005, p. 163-171.

Research output: Contribution to journalConference article

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AU - Son, Jin Ho

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AU - Kim, Tae Song

AU - Park, Hyung-Ho

AU - Kim, Hwan

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AB - Much attention has been paid to PZT thick films on Si-based substrate since they began to be used as piezoelectric actuators and sensors with introduction of MEMS technology and screen printing method. However, the thick films made just by screen printing method have high porosity as compared with bulk product, and the PZT thick films on Si-based substrate have problems regarding degradation of active materials and interface properties owing to inter-diffusion or reaction between Si substrate and PZT materials at high temperature for sintering. Thus we have fabricated screen printed PZT thick films on Si substrate using screen printing method and sol infiltration forenhancing densification. New ethanol based photo-sensitive (self-pattem-able) sol and conventional diol based sol were used in order to compare influence of patterning process and investigate adoptability in device process for biochip. Thick films with relative high densities at low temperature, 800°C and without inter-diffusion and reaction between the layers and thick film were accomplished. And it was revealed that the PZT thick film treated by ethanol based self pattern-able sol showed better electrical properties as well as better pattern-ability, and consequently it was applicable to cantilever based biochip without additional PZT film patterning process.

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