MassImpermeableBoundaryValue
MassImpermeableBoundaryValue[pred,vars,pars]
represents a mass impermeable boundary condition for PDEs with predicate pred indicating where it applies, with model variables vars and global parameters pars.
MassImpermeableBoundaryValue[pred,vars,pars,lkey]
represents a mass impermeable boundary condition with local parameters specified in pars[lkey].
Details
- MassImpermeableBoundaryValue specifies a boundary condition for MassTransportPDEComponent and is used as part of the modeling equation:
- MassImpermeableBoundaryValue is typically used to model a mass species impermeable boundary.
- MassImpermeableBoundaryValue models a boundary where there is no mass species flux across it with dependent variable
in [![TemplateBox[{InterpretationBox[, 1], {"mol", , "/", , {"m", ^, 3}}, moles per meter cubed, {{(, "Moles", )}, /, {(, {"Meters", ^, 3}, )}}}, QuantityTF]](Files/MassImpermeableBoundaryValue.en/4.png "TemplateBox[{InterpretationBox[, 1], {\"mol\", , \"/\", , {\"m\", ^, 3}}, moles per meter cubed, {{(, \"Moles\", )}, /, {(, {\"Meters\", ^, 3}, )}}}, QuantityTF]")
], independent variables 
in [![TemplateBox[{InterpretationBox[, 1], "m", meters, "Meters"}, QuantityTF]](Files/MassImpermeableBoundaryValue.en/6.png "TemplateBox[{InterpretationBox[, 1], \"m\", meters, \"Meters\"}, QuantityTF]")
] and time variable 
in [![TemplateBox[{InterpretationBox[, 1], "s", seconds, "Seconds"}, QuantityTF]](Files/MassImpermeableBoundaryValue.en/8.png "TemplateBox[{InterpretationBox[, 1], \"s\", seconds, \"Seconds\"}, QuantityTF]")
]. - Stationary variables vars are vars={c[x1,…,xn],{x1,…,xn}}.
- Time-dependent variables vars are vars={c[t,x1,…,xn],t,{x1,…,xn}}.
- The non-conservative time-dependent mass transport model MassTransportPDEComponent is based on a convection-diffusion model with mass diffusivity
, mass convection velocity vector 
, mass reaction rate 
and mass source term 
: - The conservative time-dependent mass transport model MassTransportPDEComponent is based on a conservative convection-diffusion model given by:
- In the non-conservative form, MassImpermeableBoundaryValue with boundary unit normal
models: - In the conservative form, MassImpermeableBoundaryValue models:
- A MassImpermeableBoundaryValue is the implicit default boundary condition for the conservative model form.
- Model parameters pars as specified for MassTransportPDEComponent.
- The following additional model parameters pars can be given:
-
parameter default symbol "BoundaryUnitNormal" Automatic 
"ModelForm" "NonConservative" 
- MassImpermeableBoundaryValue is a special case of MassFluxValue where the mass flux
is 0. - MassImpermeableBoundaryValue evaluates to a NeumannValue.
- The boundary predicate pred can be specified as in NeumannValue.
- If the MassImpermeableBoundaryValue depends on parameters
that are specified in the association pars as …,keypi…,pivi,…], the parameters 
are replaced with 
.
Examples
open allclose allBasic Examples (1)
Scope (3)
Define model variables vars for a transient acoustic pressure field with model parameters pars and a specific boundary condition parameter:
Define model variables vars for a transient acoustic pressure field with model parameters pars and multiple specific parameter boundary conditions:
The implicit default boundary condition changes depending on the model form. For a conservative model, an implicit Neumann 0 boundary condition is equivalent to specifying an impermeable boundary condition. For a non-conservative model, an implicit Neumann 0 boundary condition is equivalent to specifying an outflow boundary condition.
Considering this, for a constant velocity field, both the conservative and non-conservative models return the same result. A comparison between the conservative and non-conservative fields are conducted based on the following models:
Set up the mass transport model variables 
:
Specify model parameters species diffusivity 
and fluid flow velocity 
:
Set up a species concentration source of 0.2 
length at the center of the left surface:
Set up an outflow flux 
of 
on the top and bottom surfaces:
Specify impermeable boundary conditions on all other sides:
Since the default boundary condition for a conservative model is an impermeable boundary, an impermeable boundary condition is added to the non-conservative model.
Text
Wolfram Research (2020), MassImpermeableBoundaryValue, Wolfram Language function, https://reference.wolfram.com/language/ref/MassImpermeableBoundaryValue.html.
CMS
Wolfram Language. 2020. "MassImpermeableBoundaryValue." Wolfram Language & System Documentation Center. Wolfram Research. https://reference.wolfram.com/language/ref/MassImpermeableBoundaryValue.html.
APA
Wolfram Language. (2020). MassImpermeableBoundaryValue. Wolfram Language & System Documentation Center. Retrieved from https://reference.wolfram.com/language/ref/MassImpermeableBoundaryValue.html