Generalized Model of Resonant Polymer-Coated Microcantilevers in Viscous Liquid Media

Cox, R. N.; Josse, Fabien; Wenzel, Michael J.; Heinrich, Stephen M.; Dufour, Isabelle

doi:10.1021/ac800269x

Cited by 17 publications

(26 citation statements)

References 16 publications

(61 reference statements)

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“…These studies were motivated by the goal of reducing the detrimental effects of fluid damping and fluid inertia, thus providing higher resonant frequencies, fres, and quality factors, Q, the latter corresponding to sharper resonance peaks. Such improvements in the resonant characteristics of the device translate into corresponding enhancements in sensor sensitivity and limit of detection, especially for liquid-phase detection [6,10]. Some of the previously mentioned studies on the use of the inplane flexural mode demonstrated both theoretically [3,4,8] and experimentally [5,7] that the improvements in the in-liquid resonant characteristics will be most pronounced in microcantilevers that are relatively short and wide.…”

Section: Introductionmentioning

confidence: 99%

Timoshenko Beam Model for Lateral Vibration of Liquid-Phase Microcantilever-Based Sensors

Schultz

Heinrich

Josse

et al. 2013

MEMS and Nanotechnology, Volume 5

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Abstract:Dynamic-mode microcantilever-based devices are potentially well suited to biological and chemical sensing applications. However, when these applications involve liquid-phase detection, fluid-induced dissipative forces can significantly impair device performance. Recent experimental and analytical research has shown that higher in-fluid quality factors (Q) are achieved by exciting microcantilevers in the lateral flexural mode. However, experimental results show that, for microcantilevers having larger width-tolength ratios, the behaviors predicted by current analytical models differ from measurements. To more accurately model microcantilever resonant behavior in viscous fluids and to improve understanding of lateral-mode sensor performance, a new analytical model is developed, incorporating both viscous fluid effects and "Timoshenko beam" effects (shear deformation and rotatory inertia). Beam response is examined for two harmonic load types that simulate current actuation methods: tip force and support rotation. Results are expressed in terms of total beam displacement and beam displacement due solely to bending deformation, which correspond to current detection methods used with microcantilever-based devices (optical and piezoresistive detection, respectively). The influences of the shear, rotatory inertia, and fluid parameters, as well as the load/detection scheme, are investigated. Results indicate that load/detection type can impact the measured resonant characteristics and, thus, sensor performance, especially at larger values of fluid resistance.

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Section: Introductionmentioning

confidence: 99%

Timoshenko Beam Model for Lateral Vibration of Liquid-Phase Microcantilever-Based Sensors

Schultz

Heinrich

Josse

et al. 2013

MEMS and Nanotechnology, Volume 5

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“…The simulation does not account for changes in resonator stiffness due to the analyte absorption; while this is a reasonable assumption for the case of thin polymeric films on top of silicon resonators as studied herein, stiffness effects may substantially change the characteristics of a mass-sensitive sensor for other conditions. 21 If the analyte concentration cA is given in parts per million (v/v), the analyte sensitivity SA may be calculated as accessed by following the link in the citation at the bottom of the page.…”

mentioning

confidence: 99%

Liquid-Phase Chemical Sensing Using Lateral Mode Resonant Cantilevers

et al. 2010

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“…The total displacement at the tip is the relevant response quantity for sensor applications that utilize optical (laser) monitoring of the tip position, while the tip's bending-deformation displacement at or near resonance will be approximately proportional to the beam's bending strain, i.e., it will correspond to the output signal of sensors that employ local piezoresistive elements for monitoring beam response (e.g., the piezoresistive Wheatstone bridge employed in [19] [20,[29][30][31]). …”

Section: Problem Statementmentioning

confidence: 99%

“…All of these studies were primarily motivated by the desire to reduce the detrimental effects of fluid damping and fluid inertia, thus providing higher resonant frequencies, fres , and quality factors, Q , the latter corresponding to sharper resonant peaks. Within the context of sensing applications, such improvements in the resonant characteristics correspond to enhancements in sensor performance metrics such as mass or chemical sensitivity and limit of detection, especially for liquid-phase detection (e.g., [20,[29][30][31]). …”

Section: Introductionmentioning

confidence: 99%

Lateral-Mode Vibration of Microcantilever-Based Sensors in Viscous Fluids Using Timoshenko Beam Theory

Schultz

Heinrich

Josse

et al. 2015

J. Microelectromech. Syst.

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To more accurately model microcantilever resonant behavior in liquids and to improve lateral-mode sensor performance, a new model is developed to incorporate viscous fluid effects and "Timoshenko beam" effects (shear deformation, rotatory inertia). The model is motivated by studies showing that the most promising geometries for lateral-mode sensing are those for which Timoshenko effects are most pronounced.Analytical solutions for beam response due to harmonic tip force and electrothermal loadings are expressed in terms of total and bending displacements, which correspond to laser and piezoresistive readouts, respectively. The influence of shear deformation, rotatory inertia, fluid properties, and actuation/detection schemes on resonant frequencies (fres) and quality factors (Q) are examined, showing that Timoshenko beam effects may reduce fres and Q by up to 40% and 23%, respectively, but are negligible for width-tolength ratios of 1/10 and lower. Comparisons with measurements (in water) indicate that the model predicts the qualitative data trends but underestimates the softening that occurs in stiffer specimens, indicating that support deformation becomes a factor. For thinner specimens the model estimates Q quite well, but exceeds the observed values for thicker specimens, showing that the Stokes resistance model employed should be extended to include pressure effects for these geometries.

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Generalized Model of Resonant Polymer-Coated Microcantilevers in Viscous Liquid Media

Cited by 17 publications

References 16 publications

Timoshenko Beam Model for Lateral Vibration of Liquid-Phase Microcantilever-Based Sensors

Timoshenko Beam Model for Lateral Vibration of Liquid-Phase Microcantilever-Based Sensors

Liquid-Phase Chemical Sensing Using Lateral Mode Resonant Cantilevers

Lateral-Mode Vibration of Microcantilever-Based Sensors in Viscous Fluids Using Timoshenko Beam Theory

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