• Title of article

    Analysis of viscosity sensitivity for liquid property detection applications based on SAW sensors

  • Author/Authors

    Chen، نويسنده , , Xi and Liu، نويسنده , , Dali، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2010
  • Pages
    8
  • From page
    1175
  • To page
    1182
  • Abstract
    An investigation of viscosity sensitivity for liquid property detection applications based on the ZnO/SiO2/Si layered structure Love mode surface acoustic wave (SAW) sensors is presented. One of our interests in this paper is to optimize the SAW viscosity sensor under the condition of temperature stability by considering the relations among electromechanical coupling coefficient, viscosity sensitivity and temperature coefficient of delay (TCD). Some important results have been obtained by solving the system of coupled electromechanical field equations and Navier–Stokes equation. It is found that the electromechanical coupling coefficient and viscosity sensitivity can be further improved by adjusting the thickness of SiO2 thin film and a zero TCD device also can be obtained by introducing a SiO2 thin film with proper thickness. We try to obtain a device which possesses the viscosity sensitivity as high as possible and has zero TCD. Another interest of this paper is to improve the traditional viscosity sensitivity expression by considering the coupling effect between the liquid viscosity and density. It is shown that the coupling effect cannot be neglected from the numerical results. This modification could make the obtained viscosity more accurate. This analysis is meaningful for the manufactures and applications of the ZnO/SiO2/Si structure Love wave sensor for liquid property detection.
  • Keywords
    Electromechanical coupling coefficient , optimization , Temperature coefficient of delay , Viscosity sensitivity , SAW sensor
  • Journal title
    Materials Science and Engineering C
  • Serial Year
    2010
  • Journal title
    Materials Science and Engineering C
  • Record number

    2101011