The slow, steady ascent of a hot solid sphere in a Newtonian fluid with strongly temperature-dependent viscosity

M. Vynnycky, M. A. O'Brien

Research output: Contribution to journalArticlepeer-review

Abstract

In this paper, we revisit, both asymptotically and numerically, the problem of a hot buoyant spherical body with a no-slip surface ascending through a Newtonian fluid that has strongly temperature-dependent viscosity. Significant analytical progress is possible for four asymptotic regimes, in terms of two dimensionless parameters: the Péclet number, Pe, and a viscosity variation parameter, â̂Š. Severe viscosity variations lead to an involved asymptotic structure that was never previously adequately reconciled numerically; we achieve this with the help of a finite-element method. Both asymptotic and numerical results are also compared with those obtained recently for the case of a spherical body having a zero-traction surface.

Original languageEnglish
Pages (from-to)231-253
Number of pages23
JournalApplied Mathematics and Computation
Volume231
DOIs
Publication statusPublished - 15 Mar 2014

Keywords

  • Asymptotics
  • Slow flow
  • Temperature-dependent viscosity

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