Chemistry, Physics and Technology of Surface

ISSN 2518-1238 (Online), ISSN 2079-1704 (Print)

The process of sorption of 3,3'-dibromtimolsulfoftalein on the surface of the gold electrode of the resonator was investigated by the method of the quartz crystal microbalance. It has been shown that under near-equilibrium conditions of an experiment linear growth of concentration of solution of organic compound within the area of small concentration changes causes a characteristic diminishing of resonance frequency. This fact has been found to be conditioned by the successive processes of a monolayer formation of matter molecules on the surface of electrode. Developed approaches can be applied to determination of effective thickness of quasi-monomolecular layers formed from the solutions.

Catchpole K.R., McCann M.J., Weber K.J., Blakers A.W. A review of thin-film crystalline silicon for solar cell applications. Part 2: Foreign substrates // Sol. Energy Mater. Sol. Cells. – 2001. – V. 68, N 2. – P. 173–215.

Yimit A., Rossberg A.G., Amemiya T., Itoh K. Thin film composite optical waveguides for sensor applications: a review // Talanta. –2005. – V. 65, N 5. – P. 1102–1109.

Collins R.W., An I., Chen C. et al. Advances in multichannel ellipsometric techniques for in-situ and real-time characterization of thin films // Thin Solid Films. – 2004. – V. 469–470. –P. 38–46.

Innocenzi P., Martucci A., Guglielmi M. et al. Electrical and structural characterisation of mesoporous silica thin films as humidity sensors // Sens. Actuators B. – 2001. – V. 76, N 1–3. – P. 299–303.

Sauerbrey G. Verwendung von Schwingquarzen zur Wägung dünner Schichten und zur Mikrowagüng // Z. Phys. Chem. – 1959.–Bd. 155.– S. 206–222.

Numara T., Okauhara M. Frequency shifts of piezoelectric quartz crystals immersed in organic liquids // Anal. Chim. Acta. – 1982. – V. 142. – P. 281–284.

Yao S.Z., Nie L.H. Some aspects of the recent development of drug ion-selective electrodes // Anal. Proc. – 1987. – V. 24, N 11. – P. 336–337.

Kanazawa K.K., Gordon J.G. The oscillation frequency of a quartz resonator in contact with liquid // Anal. Chem. Acta. – 1985. – V. 175. – P. 99–105.

Schumacher R. Die Quarzmikrowaage: Eine neue Meßtechnik zur in-situ-Untersuchung des Phasengrenzbereiches fest/flüssig// Angew. Chem. – 1990. – V. 102, N 4. – P. 347–361.

Shen D., Kang Q., Zhang P. et al. Frequency response to liquid density of a piezoelectric quartz crystal sensor with longitudinal wave // Anal. Chim. Acta. – 2004. – V. 525, N 2. – P. 205–211.

Yao S.Z., Zhou T.A. Dependence of the oscillation frequency of a piezoelectric crystal on the physical parameters of liquids // Anal. Chim. Acta. – 1988. – V. 212. – P. 61–72.

Martin S.J., Frye G.C., Ricco A.J., Senturia S.D. Effect of surface roughness on the response of thickness-shear mode resonators in liquids // Anal. chem. – 1993. – v. 65, N 20. – P. 2910–2922.

Ichinose I., Senzu H., Kunitake T. Stepwise Adsorption of Metal Alkoxides on Hydrolyzed Surfaces A Surface Sol-Gel Process // Chem. Lett. – 1996. – V. 25, N 10. – P. 831–832.

Martin S.J., Granstaff V.E, Frye G.C. Characterization of a quartz crystal microbalance with simultaneous mass and liquid loading // Anal. chem. – 1991. – V. 63, N 20. – P. 2272–2281.

Ballato A. Frequency-Temperature-load Capacitance Behavior of Resonators for TCXO Application // IEEE Trans. Sonics Ultrason. – 1978. – V. 25, N 4. – P. 185–191.

Gotoh K., Nakata Y. The detergency phenomena of a solid oily contaminant assessed with a quartz crystal microbalance (QCM) // J. Oil Chem. Soc. Jpn. – 2004. – V. 53. – P. 489–454.

Gotoh K, Tagawa Y, Tabata I. A quartz crystal microbalance simulation to examine the effect of ultraviolet light treatment on characteristics of polyethylene surface// J. Oleo. Sci. – 2008. – V. 57, N 9. – Р. 495–501.

Nomura T., Watanabe M., West T.S. Behaviour of piezoelectric quartz crystals in solutions with application to the determination of iodide // Anal. Chim. Acta. – 1985. – V. 175. – P. 107–116.

Кузнецов Л.А., Припачкин В.И., Милонов М.В. Исследование эффективности автогенераторного метода измерения для пьезокварцевого микровзвешивания в жидкой среде // Датчики и системы. – 2004. – № 3.– С. 39–42.

Бельков В.М., Малиновская Л.М. Пьезоэлектрический метод определения примесей в жидкостях // ЖАХ. – 1984. – Т. 39, № 9. – с. 1614–1620.