The drag on a microcantilever oscillating near a wall

R. J. CLARKE; S. M. COX; P. M. WILLIAMS; O. E. JENSEN

doi:10.1017/S0022112005006907

Abstract

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Motivated by devices such as the atomic force microscope, we compute the drag experienced by a cylindrical body of circular or rectangular cross-section oscillating at small amplitude near a plane wall. The body lies parallel to the wall and oscillates normally to it; the body is assumed to be long enough for the dominant flow to be two-dimensional. The flow is parameterized by a frequency parameter $\gamma^2$ (a Strouhal number) and the wall–body separation $\Delta$ (scaled on body radius). Numerical solutions of the unsteady Stokes equations obtained using finite-difference computations in bipolar coordinates (for circular cross-sections) and boundary-element computations (for rectangular cross-sections) are used to determine the drag on the body. Numerical results are validated and extended using asymptotic predictions (for circular cylinders) obtained at all extremes of $(\gamma,\Delta)$-parameter space. Regions in parameter space for which the wall has a significant effect on drag are identified.

Crossref Citations

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Clarke, R. J. Jensen, O. E. Billingham, J. Pearson, A. P. and Williams, P. M. 2006. Stochastic Elastohydrodynamics of a Microcantilever Oscillating Near a Wall. Physical Review Letters, Vol. 96, Issue. 5,

Clarke, R.J Jensen, O.E Billingham, J and Williams, P.M 2006. Three-dimensional flow due to a microcantilever oscillating near a wall: an unsteady slender-body analysis. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, Vol. 462, Issue. 2067, p. 913.

Paul, M R Clark, M T and Cross, M C 2006. The stochastic dynamics of micron and nanoscale elastic cantilevers in fluid: fluctuations from dissipation. Nanotechnology, Vol. 17, Issue. 17, p. 4502.

Basak, Sudipta and Raman, Arvind 2007. Hydrodynamic coupling between micromechanical beams oscillating in viscous fluids. Physics of Fluids, Vol. 19, Issue. 1,

Harrison, Christopher Tavernier, Emmanuel Vancauwenberghe, Olivier Donzier, Eric Hsu, Kai Goodwin, Anthony R.H. Marty, Frederic and Mercier, Bruno 2007. On the response of a resonating plate in a liquid near a solid wall. Sensors and Actuators A: Physical, Vol. 134, Issue. 2, p. 414.

Clark, M.T. and Paul, M.R. 2007. The stochastic dynamics of an array of atomic force microscopes in a viscous fluid. International Journal of Non-Linear Mechanics, Vol. 42, Issue. 4, p. 690.

Clarke, R. J. Jensen, O. E. and Billingham, J. 2008. Three-dimensional elastohydrodynamics of a thin plate oscillating above a wall. Physical Review E, Vol. 78, Issue. 5,

Hennemeyer, Marc Burghardt, Stefan and Stark, Robert W. 2008. Cantilever Micro-rheometer for the Characterization of Sugar Solutions. Sensors, Vol. 8, Issue. 1, p. 10.

Williams, Phil 2008. Handbook of Molecular Force Spectroscopy. p. 143.

Raman, Arvind Melcher, John and Tung, Ryan 2008. Cantilever dynamics in atomic force microscopy. Nano Today, Vol. 3, Issue. 1-2, p. 20.

Goodwin, Anthony R. H. Jakeways, Claire V. and de Lara, Maria Manrique 2008. A MEMS Vibrating Edge Supported Plate for the Simultaneous Measurement of Density and Viscosity: Results for Nitrogen, Methylbenzene, Water, 1-Propene,1,1,2,3,3,3-hexafluoro-oxidized-polymd, and Polydimethylsiloxane and Four Certified Reference Materials with Viscosities in the Range (0.038 to 275) mPa·s and Densities between (408 and 1834) kg·m−3 at Temperatures from (313 to 373) K and Pressures up to 60 MPa. Journal of Chemical & Engineering Data, Vol. 53, Issue. 7, p. 1436.

Clark, M. T. and Paul, M. R. 2008. The stochastic dynamics of rectangular and V-shaped atomic force microscope cantilevers in a viscous fluid and near a solid boundary. Journal of Applied Physics, Vol. 103, Issue. 9,

Chadwick, Richard S. and Liao, Zhijie 2008. High-Frequency Oscillations of a Sphere in a Viscous Fluid near a Rigid Plane. SIAM Review, Vol. 50, Issue. 2, p. 313.

Tung, Ryan C. Jana, Anirban and Raman, Arvind 2008. Hydrodynamic loading of microcantilevers oscillating near rigid walls. Journal of Applied Physics, Vol. 104, Issue. 11,

Goodwin, Anthony R. H. 2009. A MEMS Vibrating Edge Supported Plate for the Simultaneous Measurement of Density and Viscosity: Results for Argon, Nitrogen, and Methane at Temperatures from (297 to 373) K and Pressures between (1 and 62) MPa. Journal of Chemical & Engineering Data, Vol. 54, Issue. 2, p. 536.

Raman, A. Reifenberger, R. Melcher, J. and Tung, R. 2009. Noncontact Atomic Force Microscopy. p. 361.

Villa, M. M. and Paul, M. R. 2009. Stochastic dynamics of micron-scale doubly clamped beams in a viscous fluid. Physical Review E, Vol. 79, Issue. 5,

Brumley, Douglas R. Willcox, Michelle and Sader, John E. 2010. Oscillation of cylinders of rectangular cross section immersed in fluid. Physics of Fluids, Vol. 22, Issue. 5,

SADER, JOHN E. BURG, THOMAS P. and MANALIS, SCOTT R. 2010. Energy dissipation in microfluidic beam resonators. Journal of Fluid Mechanics, Vol. 650, Issue. , p. 215.

Fornari, Antoine Sullivan, Matthew Chen, Hua Harrison, Christopher Hsu, Kai Marty, Frederic and Mercier, Bruno 2010. Experimental Observation of Inertia-Dominated Squeeze Film Damping in Liquid. Journal of Fluids Engineering, Vol. 132, Issue. 12,

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The drag on a microcantilever oscillating near a wall

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