1,035 research outputs found
On the scaling of entropy viscosity in high order methods
In this work, we outline the entropy viscosity method and discuss how the
choice of scaling influences the size of viscosity for a simple shock problem.
We present examples to illustrate the performance of the entropy viscosity
method under two distinct scalings
Suitable weak solutions of the Navier-Stokes equations constructed by a space-time numerical discretization
We prove that weak solutions obtained as limits of certain numerical
space-time discretizations are suitable in the sense of Scheffer and
Caffarelli-Kohn-Nirenberg. More precisely, in the space-periodic setting, we
consider a full discretization in which the theta-method is used to discretize
the time variable, while in the space variables we consider appropriate
families of finite elements. The main result is the validity of the so-called
local energy inequality.Comment: 16 page
A converse to Fortin's Lemma in Banach spaces
The converse of Fortin's Lemma in Banach spaces is established in this Note
Mollification in strongly Lipschitz domains with application to continuous and discrete De Rham complex
We construct mollification operators in strongly Lipschitz domains that do
not invoke non-trivial extensions, are stable for any real number
, and commute with the differential operators ,
, and . We also construct mollification
operators satisfying boundary conditions and use them to characterize the
kernel of traces related to the tangential and normal trace of vector fields.
We use the mollification operators to build projection operators onto general
-, - and -conforming
finite element spaces, with and without homogeneous boundary conditions. These
operators commute with the differential operators , ,
and , are -stable, and have optimal approximation
properties on smooth functions
Numerical Simulations of Bouncing Jets
Bouncing jets are fascinating phenomenons occurring under certain conditions
when a jet impinges on a free surface. This effect is observed when the fluid
is Newtonian and the jet falls in a bath undergoing a solid motion. It occurs
also for non-Newtonian fluids when the jets falls in a vessel at rest
containing the same fluid.
We investigate numerically the impact of the experimental setting and the
rheological properties of the fluid on the onset of the bouncing phenomenon.
Our investigations show that the occurrence of a thin lubricating layer of air
separating the jet and the rest of the liquid is a key factor for the bouncing
of the jet to happen.
The numerical technique that is used consists of a projection method for the
Navier-Stokes system coupled with a level set formulation for the
representation of the interface. The space approximation is done with adaptive
finite elements. Adaptive refinement is shown to be very important to capture
the thin layer of air that is responsible for the bouncing
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