Recent experimental and analytical research has shown that higher in-fluid quality factors (Q) are achieved by actuating microcantilevers in the lateral flexural mode, especially for microcantilevers having larger width-to-length ratios. However, experimental results show that for these geometries the resonant characteristics predicted by the existing analytical models differ from the measurements. A recently developed analytical model to more accurately predict the resonant behaviour of these devices in viscous fluids is described. The model incorporates viscous fluid effects via a Stokes-type fluid resistance assumption and `Timoshenko beam\u27 effects (shear deformation and rotatory inertia). Unlike predictions based on Euler-Bernoulli beam theory, the new theoretical results for both resonant frequency and Q exhibit the same trends as seen in the experimental data for in-water measurements as the beam slenderness decreases. An analytical formula for Q is also presented to explicitly illustrate how Q depends on beam geometry and on beam and fluid properties. Beam thickness effects are also examined and indicate that the analytical results yields good numerical estimates of Q for the thinner (5 μm) specimens tested, but overestimate Q for the thicker (20 μm) specimens, thus suggesting that a more accurate fluid resistance model should be introduced in the future for the latter case

Beardslee, Luke A.

Brand, Oliver

Dufour, Isabelle

Heinrich, Stephen M.

Josse, Fabien

Nigro, Nicholas J.

Schultz, Joshua A.

Micro & Nano Letters

English

Schultz, Joshua

Heinrich, Stephen

Nigro, Nicholas

Beardslee, Luke

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Timoshenko beam effects in lateral-mode microcantilever-based sensors in liquids

epublications@Marquette

Timoshenko Beam Effects in Lateral-mode Microcantilever-based Sensors in Liquids

Joshua A. Schultz

Stephen M. Heinrich

Fabien Josse

Nicholas J. Nigro

Isabelle Dufour

Luke A. Beardslee

Oliver Brand

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Timoshenko beam effects in lateral‐mode microcantilever‐based sensors in liquids

Hal-Diderot

Marquette Universitye-Publications@MarquetteCivil and Environmental Engineering FacultyResearch and PublicationsCivil and Environmental Engineering, Departmentof1-1-2013Timoshenko Beam Effects in Lateral-ModeMicrocantilever-Based Sensors in Liquids(proceedings)Joshua A. SchultzMarquette UniversityStephen M. HeinrichMarquette University, stephen.heinrich@marquette.eduFabien JosseMarquette University, fabien.josse@marquette.eduNicholas J. NigroMarquette UniversityIsabelle DufourUniversité de BordeauxSee next page for additional authorsPublished version. Published as part of the proceedings of the conference, 10th InternationalWorkshop on Nanomechanical Sensing NMC 2013, 2013: 143-144. Publisher Link. © 2013 StanfordUniversity. Used with permission.AuthorsJoshua A. Schultz, Stephen M. Heinrich, Fabien Josse, Nicholas J. Nigro, Isabelle Dufour, Luke A. Beardslee,and Oliver BrandThis conference proceeding is available at e-Publications@Marquette: https://epublications.marquette.edu/civengin_fac/17             Proceedings of 2013 Nanomechanical Sensing Workshop                    J.A. Schultz, S.M. Heinrich, F. Josse, N.J. Nigro, Stanford University, Stanford, CA                                       I. Dufour, L.A. Beardslee, and O. Brand    TIMOSHENKO BEAM EFFECTS IN LATERAL-MODE  MICROCANTILEVER-BASED SENSORS IN LIQUIDS  Joshua A. Schultz,1 Stephen M. Heinrich,1 Fabien Josse,2 Nicholas J. Nigro,3 Isabelle Dufour,4  Luke A. Beardslee,5 and Oliver Brand5 Departments of 1Civil, Construction and Environmental, 2Electrical and Computer, and  3Mechanical Engineering, Marquette University, Milwaukee, WI, USA; 4Université de Bordeaux, CNRS, IMS Laboratory, Talence, France; 5School of Electrical and Computer Engineering, Georgia Institute of Technology, Atlanta, GA, USA  Introduction and Motivation  Dynamic-mode microcantilever-based devices are well suited to biological and chemical sensing applications. However, these applications often necessitate liquid-phase sensing, introducing significant fluid-induced inertial and dissipative forces which reduce resonant frequencies (fres) and quality factors (Q) and, thus, adversely affect sensitivity and limit of detection. In an effort to mitigate some of these fluid effects, the use of unconventional resonant modes of microcantilever-based sensors has been investigated [1-4]. Recent analytical [2,3] and experiment-al [4] research has shown that higher in-fluid Q is achieved by exciting microcantilevers in lateral flexural (Fig. 1), which reduces the viscous energy dissipation in the fluid as compared to the transverse (out-of-plane) mode. In particular, both theoretical and experimental results show that the lateral-mode designs offering the most promise in liquid-phase sensing applications are those for which the micro-beams are relatively short and wide. However, such geometries may violate the assump-tions employed in Euler-Bernoulli (EB) beam theory due to the large width-to-length ratio. This may be observed, for example, in the deviation between EB predictions and experimental data for  fres and Q for short, wide cantilev-ers, for which EB theory overestimates the results [4]. To understand the behavior of such sensor geometries, a beam-fluid interaction model that accounts for “Timoshenko beam” (TB) effects (shear deformation and rotatory inertia) is warranted and is the focus of this study.  Fig. 1: Microcantilever-based Chemical Sensor: Thermal Resistors near Support to Excite Lateral (In-plane) Bending [4] Modeling Assumptions The major assumptions employed in the new model are (1) viscous dissipation in the fluid is the dominant loss mechanism; (2) the cross section is relatively thin (thickness h<<width b), so the fluid resistance associated with the pressure on the smaller faces is negligible compared with that due to the fluid’s shear resistance on the larger faces; (3) the shear stress exerted by the fluid on the beam is approximated by local application of the classical solution of Stokes’s second problem for har-monic motion of an infinite rigid plate in a viscous fluid.  Boundary Value Problem (BVP) By modeling the microcantilever as a Timoshenko beam with distributed Stokes-type fluid resistance, two 4th-order PDEs which govern the total deflection, v , and the rotation angle of the cross section, φ, may be derived. (Overbars denote dimensionless quantities.) Employing separation of variables leads to two 4th-order ODEs for the spatially dependent deflection and rotation fields, ( )V ξand Φ(ξ), where ξ =x/L is a normalized coordinate:    ( ) ( )[ ]( )[ ] ( )[ ]{ }3 2 23 2 2 311 1 1 0,V r s i Vi r s i Vλ λ ζλ λ ζ λ λ ζ′′′′ ′′+ + + −− + − − + − =(1a,b)  (Equation (1b) for Φ(ξ) is identical in form.) Quantities Vand Φ are the amplitudes of the total beam deflection (bending plus shear) and the rotation angle (associated with bending only). The TB parameters are defined as the rotational inertia parameter, 2 2I/r AL≡ , and the shear deformation parameter, 2 2EI/s kAGL≡ , where A and I are the cross section’s area and second moment of area, E and G are the Young’s modulus and shear modulus, k = 5/6 is the shear coefficient, and L is beam length. Parameters λ and ζ are the frequency and fluid resistance parameters, which are related to the fundamental system parameters by           1/41/4 2 24 22 1/2 34812,  fbbL LEb hb Eρ ηρ ωλ ζ ρ≡ ≡⎛ ⎞⎛ ⎞ ⎜ ⎟⎜ ⎟ ⎜ ⎟⎝ ⎠ ⎝ ⎠,      (2a,b) 143             Proceedings of 2013 Nanomechanical Sensing Workshop                    J.A. Schultz, S.M. Heinrich, F. Josse, N.J. Nigro, Stanford University, Stanford, CA                                       I. Dufour, L.A. Beardslee, and O. Brand     Fig. 2: Resonant Frequency Comparison (Lateral Mode in Water, h=7.02 μm, E=151 GPa): Current Model, Euler-Bernoulli Model, and Experimental Data.   where bρ  is the density of the beam material, fρ  and η  are the density and viscosity of the fluid, and ω  is the driving (and thus the response) frequency (rad/s). Imposed boundary conditions correspond to electrothermal harmonic excitation via integrated heating resistors near the base of the cantilever (Fig. 1) and are given by     0(0) 0, (0) , (1) 0, (1) (1) 0V Vθ ′ ′= Φ = Φ = −Φ = ,     (3a-d) where 0θ  represents the amplitude of the “effective support rotation” imparted by the heating resistors [3].    Results The BVP defined by (1a,b) and (3a-d) was solved analytically and the results expressed in terms of two “output signals”: total tip displacement and bending tip displacement, corresponding respectively to optical and piezoresistive detection methods. Resonant frequency (fres) and Q were extracted from the theoretical beam response and were insensitive to the type of output signal for the fluid resistance values considered. Results (Figs. 2 and 3) show that the new model reproduces experimental trends in fres and Q for lateral-mode microcantilevers at higher b/L ratios (i.e., for the high-Q devices for which EB models prove inadequate). Over the practical ranges of system parameters considered, the results indicate that TB effects can account for a reduction in fres and Q of up to ~40% and ~25%, respectively, but have effects of less than 2% when L/b>10. The more accurate frequency estimates are smaller than the EB results because the Timoshenko beam model has lower stiffness (due to shear deformation) and greater mass (due to rotatory inertia).  These effects therefore lead to the departure from the linear EB frequency results (Fig. 2). Similar conclusions apply to the Q comparisons among the experimental data        Fig. 3: Quality Factor Comparison (Lateral Mode in Water,   h=7.02 μm, E=151 GPa): Current Model, Euler-Bernoulli Model, and Experimental Data [4].   and the TB and EB models (Fig. 3). To show more explicitly the effect of system parameters on Q, a new analytical equation has been established: 1/4 1.902 1.422 0.8111/2 32 20.7182 1 0.0794 0.0670bfhb E b b EQL L L Gρρ η⎡ ⎤⎛ ⎞ ⎛ ⎞ ⎛ ⎞ ⎛ ⎞≈ − −⎜ ⎟ ⎢ ⎥⎜ ⎟ ⎜ ⎟ ⎜ ⎟⎜ ⎟ ⎝ ⎠ ⎝ ⎠ ⎝ ⎠⎢ ⎥⎝ ⎠ ⎣ ⎦.(4)  The bracketed expression, obtained by fitting the results of the new model, represents a correction factor associated with shear deformation and rotatory inertia effects, which reduces the EB result [2] appearing in front of the correction factor. The results of (4) are within 2.6% of those generated by the analytical model over the following parameter ranges: ζ = (0, 0.05), r = (0, 0.2), /E kG =(0, 3).    References [1] Sharos, L.B., Raman, A., Crittenden, S., and Reifenberger, R., “Enhanced Mass Sensing Using Torsional and Lateral Resonances in Microcantilevers,” APL, 2004, 4638-4640. [2] Heinrich, S.M., Maharjan, R., Beardslee, L., Brand, O., Dufour, I., and Josse, F., “An Analytical Model for In-Plane Flexural Vibrations of Thin Cantilever-Based Sensors in Viscous Fluids: Applications to Chemical Sensing in Liquids,” Proc., Int’l Workshop on Nanomechanical Cantilever Sensors, Banff, Canada, May 26-28, 2010, 2 pp. [3] Heinrich, S.M., Maharjan, R., Dufour, I., Josse, F., Beardslee, L.A., and Brand, O., “An Analytical Model of a Thermally Excited Microcantilever Vibrating Laterally in a Viscous Fluid,” Proc., IEEE Sensors 2010 Conference, Waikoloa, Hawaii, November 1-4, 2010, 1399-1404. [4] Beardslee, L.A., Josse, F., Heinrich, S.M., Dufour, I., and Brand, O., “Geometrical Considerations for the Design of Liquid-Phase Biochemical Sensors Using a Cantilever’s Fundamental In-Plane Mode,” Sens. and Act. B, 2012, 7-14.  0 250 500 750 1000 1250 1500 1750 2000025050075010001250150017502000225025002750b/L2 [m-1]Resonant Frequency [kHz]  Current Model (Timoshenko Theory)Exp Data: L=200 μm; b=(60, 75) μmExp. Data: L=400 μm; b=(45, 60, 75, 90) μmExp Data: L=600 μm; b=(45, 60, 75) μmExp Data: L=800 μm; b=(45, 60, 75, 90) μmExp Data: L=1000 μm; b=(45, 60, 75, 90) μmEuler-Bernoulli Theory [2]0 5 10 15 20 25 30 35 40 4505101520253035404550b1/2/L [m-1/2]Quality Factor Q  Current Model (Timoshenko Theory) Exp. Data: L=200 μm; b=(45, 60, 75) μmExp. Data: L=400 μm; b=(45, 60, 75, 90) μmExp. Data: L=600 μm; b=(45, 60, 75, 90) μmExp. Data: L=800 μm; b=(45, 60, 75, 90) μmExp. Data: L=1000 μm; b=(45, 60, 75, 90) μmEuler-Bernoulli Theory [2]144

Timoshenko Beam Effects in Lateral-Mode Microcantilever-Based Sensors in Liquids (proceedings)

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Timoshenko Beam Effects in Lateral-mode Microcantilever-based Sensors in Liquids

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