Viscous potential flow

D. D. JOSEPH

doi:10.1017/S0022112002003634

Abstract

Potential flows ${\bm u} = {\bm\nabla} \phi$ are solutions of the Navier–Stokes equations for viscous incompressible fluids for which the vorticity is identically zero. The viscous term $\mu \nabla^2 {\bm u} = \mu{\bm \nabla}\nabla^2\phi$ vanishes, but the viscous contribution to the stress in an incompressible fluid (Stokes 1850) does not vanish in general. Here, we show how the viscosity of a viscous fluid in potential flow away from the boundary layers enters Prandtl's boundary layer equations. Potential flow equations for viscous compressible fluids are derived for sound waves which perturb the Navier–Stokes equations linearized on a state of rest. These linearized equations support a potential flow with the novel features that the Bernoulli equation and the potential as well as the stress depend on the viscosity. The effect of viscosity is to produce decay in time of spatially periodic waves or decay and growth in space of time-periodic waves.

In all cases in which potential flows satisfy the Navier–Stokes equations, which includes all potential flows of incompressible fluids as well as potential flows in the acoustic approximation derived here, it is neither necessary nor useful to put the viscosity to zero.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Imaoka, Randall T. and Sirignano, William A. 2005. A generalized analysis for liquid-fuel vaporization and burning. International Journal of Heat and Mass Transfer, Vol. 48, Issue. 21-22, p. 4342.

Sirakov, B. T. Greitzer, E. M. and Tan, C. S. 2005. A note on irrotational viscous flow. Physics of Fluids, Vol. 17, Issue. 10,

Joseph, Daniel D. 2006. Potential flow of viscous fluids: Historical notes. International Journal of Multiphase Flow, Vol. 32, Issue. 3, p. 285.

Funada, T. Joseph, D.D. Saitoh, M. and Yamashita, S. 2006. Liquid jet in a high Mach number air stream. International Journal of Multiphase Flow, Vol. 32, Issue. 1, p. 20.

Sirwah, Magdy A. 2007. Nonlinear Kelvin–Helmholtz instability of magnetized surface waves on a subsonic gas–viscous potential liquid interface. Physica A: Statistical Mechanics and its Applications, Vol. 375, Issue. 2, p. 381.

Zakaria, Kadry 2008. Standing waves between immiscible liquids inside an infinite boxed basin. Journal of Physics A: Mathematical and Theoretical, Vol. 41, Issue. 17, p. 175501.

Padrino, J.C. Funada, T. and Joseph, D.D. 2008. Purely irrotational theories for the viscous effects on the oscillations of drops and bubbles. International Journal of Multiphase Flow, Vol. 34, Issue. 1, p. 61.

Sirwah, Magdy A. 2008. Non-linear temporal dynamics of two-mode interactions of magnetized flow. International Journal of Non-Linear Mechanics, Vol. 43, Issue. 5, p. 416.

Zakaria, K. Sirwah, M. and Assaf, A. 2009. Nonlinear Marangoni instability of a liquid jet in the presence of electric field. ZAMM - Journal of Applied Mathematics and Mechanics / Zeitschrift für Angewandte Mathematik und Mechanik, Vol. 89, Issue. 11, p. 902.

Zakaria, Kadry 2009. Nonlinear interfacial waves in streaming flows. Quarterly of Applied Mathematics, Vol. 67, Issue. 2, p. 265.

Buresti, Guido 2009. Notes on the role of viscosity, vorticity and dissipation in incompressible flows. Meccanica, Vol. 44, Issue. 4, p. 469.

Umurhan, O. M. and Shaviv, G. 2009. Linear dynamics of weakly viscous accretion disks: a disk analog of Tollmien-Schlichting waves. Astronomy & Astrophysics, Vol. 497, Issue. 1, p. 1.

Zakaria, Kadry 2011. Stability of resonant interfacial waves in the presence of uniform magnetic field. Nonlinear Dynamics, Vol. 66, Issue. 4, p. 457.

Zakaria, Kadry and Sirwah, Magdy A 2012. Nonlinear behavior of the surface waves between two magnetic fluid layers. Physica Scripta, Vol. 86, Issue. 6, p. 065704.

GOH, BING HUI TERENCE KLASEBOER, EVERT and KHOO, BOO CHEONG 2012. BEM SIMULATIONS OF POTENTIAL FLOW WITH VISCOUS EFFECTS AS APPLIED TO AN ACOUSTIC BUBBLE. International Journal of Modern Physics: Conference Series, Vol. 19, Issue. , p. 1.

Obied Allah, M. H. 2013. Viscous potential flow analysis of magnetohydrodynamic interfacial stability through porous media. Indian Journal of Pure and Applied Mathematics, Vol. 44, Issue. 4, p. 419.

Bouwhuis, Wilco Winkels, Koen G. Peters, Ivo R. Brunet, Philippe van der Meer, Devaraj and Snoeijer, Jacco H. 2013. Oscillating and star-shaped drops levitated by an airflow. Physical Review E, Vol. 88, Issue. 2,

El-Sayed, M.F. Eldabe, N.T. Haroun, M.H. and Mostafa, D.M. 2014. Nonlinear electroviscoelastic potential flow instability theory of two superposed streaming dielectric fluids. Canadian Journal of Physics, Vol. 92, Issue. 10, p. 1249.

Weijermars, R. 2014. Visualization of space competition and plume formation with complex potentials for multiple source flows: Some examples and novel application to Chao lava flow (Chile). Journal of Geophysical Research: Solid Earth, Vol. 119, Issue. 3, p. 2397.

Weijermars, R. Dooley, T. P. Jackson, M. P. A. and Hudec, M. R. 2014. Rankine models for time‐dependent gravity spreading of terrestrial source flows over subplanar slopes. Journal of Geophysical Research: Solid Earth, Vol. 119, Issue. 9, p. 7353.

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Viscous potential flow

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