Theoretical analysis on response mechanism of polymer-coated chemical sensor based Love wave in viscoelastic media

Sensors and Actuators, B: Chemical

Volumn 138, Issue 2, 2009, Pages 432-440

  Wang, Wen ^a   He, Shitang ^a  

^a INSTITUTE OF ACOUSTICS   (China)

Author keywords

Chemical sensor; Love wave; Polymer; Response mechanism

Indexed keywords

CHEMICAL INTERFACES; DISPERSION EQUATIONS; EXPERIMENTAL DATUM; GUIDING LAYERS; LOVE WAVE; LOVE WAVE CHEMICAL SENSORS; OPTIMAL DESIGN PARAMETERS; ORGANOPHOSPHOROUS COMPOUNDS; POLYMETHYLMETHACRYLATE; QUARTZ SUBSTRATES; RESPONSE MECHANISM; RUBBERY POLYMERS; SENSOR PERFORMANCE; SENSOR SENSITIVITIES; SURFACE ACOUSTIC WAVES; TAYLOR-SERIES; THEORETICAL MODELS; VELOCITY CHANGES; VISCOELASTIC MEDIAS; VISCOELASTIC POLYMERS;

ACOUSTIC SURFACE WAVE DEVICES; ACOUSTIC WAVES; ACOUSTICS; ADSORPTION; CHEMICAL ANALYSIS; CHEMICAL COMPOUNDS; CHEMICAL SENSORS; ELECTRIC NETWORK ANALYSIS; OPTIMIZATION; OXIDE MINERALS; PLASTIC COATINGS; POLYMERS; QUARTZ; WAVE PROPAGATION;

POLYMER FILMS;

EID: 64549154835     PISSN: 09254005     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.snb.2009.03.006     Document Type: Article

References (19)

1. Du J., and Harding G.L. A multilayer structure for love-mode acoustic sensor. Sens. Actuators A 65 (1998) 152-159
2. 2 protective layer. Sens. Actuators B 76 (2001) 147-151
3. Gizeli E. Design considerations for the acoustic waveguide biosensor. Smart Mater. Struct. 6 (1997) 700-706
4. Kovacs G., Vellekoop M.J., and Haueis R. A love wave sensor for (bio)chemical sensing in liquids. Sens. Actuators A 43 (1994) 38-43
5. Gizeli E., Bender F., Rasmusson A., and Saha K. Sensitivity of the acoustic waveguide biosensor to protein binding as a function of the waveguide properties. Biosens. Bioelectron. 18 (2003) 1399-1406
6. Zimmermann C., Rediere D., and Dejous C. A love-wave gas sensor coated with functionalized polysiloxane for sensing organophosphorus compounds. Sens. Actuators B 76 (2001) 86-94
7. Jakoby B., Ismail G.M., and Byfield M.P. A novel molecularly imprinted thin film applied to a Love wave gas sensor. Sens. Actuators A 76 (1999) 93-97
8. Kadota M., Yoneda T., and Fujmoto K. Very small sized resonator filter using shearing horizontal wave on quartz. Jpn. J. Appl. Phys. 40 (2001) 3718-3721
9. Campbell C.K. Surface Acoustic Wave Devices for Mobile and Wireless Communication (1998), Academic Press, San Diego p. 214
10. 3 substrates. Electron. Lett. 36 (2000) 1672-1673
11. Martin S.J., Frye G.C., and Senturia S.D. Dynamics and response of polymer-coated surface acoustic wave devices: effect of viscoelastic properties and film resonance. Anal. Chem. 66 (1994) 2201-2129
12. Harding G.L., and Du J. Design and properties of quartz-based Love wave acoustic sensors incorporating silicon dioxide and PMMA guiding layers. Smart Mater. Struct. 6 (1997) 716-720
13. Royer D., and Dieulesaint E. Elastic Waves in Solids. Part I. Free and Guided Propagation (1996), Masson, Paris
14. Zimmermann C., Rebiere D., and Dejous C. Love-waves to improve chemical sensors sensitivity: theoretical and experimental comparison of acoustic modes. Proc. IEEE Int. Frequency Contr. Sym. 1 (2002) 281-288
15. Jakoby B., and Vellekoop M. Properties of Love waves: applications in sensors. Smart Mater. Struct. 6 (1997) 668-679
16. Kielczynski P. Attenuation of Love waves in low-loss media. J. Appl. Phys. 82 (1997) 5932-5937
17. Shen Y.T., Shen C.Y., and Wu L. Design of ST-cut quartz surface acoustic wave chemical sensors. Sens. Actuators B 85 (2002) 277-283
18. Auld B. Acoustic fields and waves in solids 1 (1973), Wiley, New York
19. McGill R.A., Abraham M.H., and Grate J.W. Choosing polymer coatings for chemical sensors. Chemtech 24 (1994) 27-37