A computational model of the cochlea using the immersed boundary method

Mathematical models of valveless pumping can be represented by either a closed loop system or an open tube system. In this paper, we present a three-dimensional model of valveless pumping in a closed loop system. We also present a two-dimensional model using an open elastic cylinder contained in a r

Biofilm processes are of interest to researchers in a variety of fields including bioremediation, oil recovery, wastewater treatment, ture, whether it is a heart valve, a flagellum, or an aggregate medicine, and dentistry. In this paper we describe how this complex, of cells, as a region in the flui

The motion of flexible fibres suspended in an incompressible fluid is of interest to researchers in a wide variety of fields, including reinforced composite materials, biotechnology, and the pulp and paper industry. In this work, we concentrate on the application to pulp fibres and demonstrate how t

We explore the theoretical foundations for the inclusion of thermal fluctuations in the immersed boundary method for simulating microscale fluid systems with immersed flexible structures, as in cellular and subcellular biology. We investigate in particular the physical validity of the thermal forcin

A computational setting for the Immersed Boundary Method employing an adaptive mesh refinement is presented. Enhanced accuracy for the method is attained locally by covering an immersed boundary vicinity with a sequence of nested, progressively finer rectangular grid patches which dynamically follow

We propose a fast, explicit numerical method for computing approximations for the immersed boundary problem in which the boundaries that separate the fluid into two regions are stiff. In the numerical computations of such problems, one frequently has to contend with numerical instability, as the sti