Effect of Surface and Interfacial Tension on the Resonance Frequency of Microfluidic Channel Cantilever

• Published in: Sensors (Basel, Switzerland) Vol. 20; no. 22; p. 6459
• Main Authors: Abraham, Rosmi, Khan, Faheem, Bukhari, Syed A., Liu, Qingxia, Thundat, Thomas, Chung, Hyun-Joong, Kim, Chun Il
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 12.11.2020; MDPI
• Subjects: Adsorption; Euler–Bernoulli beam theory; Hypotheses; interfacial tension; microchannel cantilever resonator; Nanowires; Sensors; surface stress; vibration resonance frequency
• ISSN: 1424-8220; 1424-8220
• DOI: 10.3390/s20226459

The bending resonance of micro-sized resonators has been utilized to study adsorption of analyte molecules in complex fluids of picogram quantity. Traditionally, the analysis to characterize the resonance frequency has focused solely on the mass change, whereas the effect of interfacial tension of the fluid has been largely neglected. By observing forced vibrations of a microfluidic cantilever filled with a series of alkanes using a laser Doppler vibrometer (LDV), we studied the effect of surface and interfacial tension on the resonance frequency. Here, we incorporated the Young–Laplace equation into the Euler–Bernoulli beam theory to consider extra stress that surface and interface tension exerts on the vibration of the cantilever. Based on the hypothesis that the near-surface region of a continuum is subject to the extra stress, thin surface and interface layers are introduced to our model. The thin layer is subject to an axial force exerted by the extra stress, which in turn affects the transverse vibration of the cantilever. We tested the analytical model by varying the interfacial tension between the silicon nitride microchannel cantilever and the filled alkanes, whose interfacial tension varies with chain length. Compared with the conventional Euler–Bernoulli model, our enhanced model provides a better agreement to the experimental results, shedding light on precision measurements using micro-sized cantilever resonators.