Divergence: Difference between revisions

From Citizendium
Jump to navigation Jump to search
imported>Paul Wormer
(New page: {{subpages}} The '''divergence''' of a differentiable vector field '''F'''('''r''') is given by the following expression, :<math> \begin{align} \boldsymbol{\nabla}\cdot \mathbf{F...)
 
imported>Paul Wormer
No edit summary
Line 10: Line 10:
where '''e'''<sub>''x''</sub>, '''e'''<sub>''y''</sub>, '''e'''<sub>''z''</sub> form an [[orthonormal basis]] of <math>\scriptstyle \mathbb{R}^3</math>. The dot stands for a [[dot product]].
where '''e'''<sub>''x''</sub>, '''e'''<sub>''y''</sub>, '''e'''<sub>''z''</sub> form an [[orthonormal basis]] of <math>\scriptstyle \mathbb{R}^3</math>. The dot stands for a [[dot product]].


The physical meaning of divergence is given by the [[continuity equation]]. Consider an incompressible fluid (gas or liquid) that is in flow. Let '''&psi;'''('''r''')  be its flux (mass per unit time passing through a unit surface)  and let &rho;('''r''') be its mass density (amount of mass per unit volume) at the same point '''r'''.  
The physical meaning of divergence is given by the [[continuity equation]]. Consider a compressible fluid (gas or liquid) that is in flow. Let '''&phi;'''('''r''',''t'')  be its [[flux]] (mass per unit time passing through a unit surface)  and let &rho;('''r''',''t'') be its mass density (amount of mass per unit volume) at the same point '''r'''.  
The flux is a [[vector]] giving the direction of flow and the density is a [[scalar]]. The continuity equation states that   
The flux is a vector field (at any point a vector gives the direction of flow), and the density is a [[scalar field]] (function). The continuity equation states that   
:<math>
:<math>
\boldsymbol{\nabla}\cdot\boldsymbol{\psi}(\mathbf{r}) = - \frac{d \rho(\mathbf{r})}{dt}.
\boldsymbol{\nabla}\cdot\boldsymbol{\phi}(\mathbf{r},t) = - \frac{d \rho(\mathbf{r},t)}{dt}.
</math>
</math>
Multiply the left- and right-hand side by an infinitesimal volume element &Delta;''V''. Then the left hand side gives the mass leaving  &Delta;''V'' minus the mass entering &Delta;''V'' (per unit time). The right-hand becomes equal to   &minus;&rho;&Delta;''V'', which is the decrease in mass per unit time. Hence the net flow of mass leaving the the volume is equal to the decrease of mass in &Delta;''V'' (both per unit time).
Multiply the left- and right-hand side by an infinitesimal volume element &Delta;''V'' containing the point '''r'''. Then the left hand side gives the mass leaving  &Delta;''V'' minus the mass entering &Delta;''V'' (per unit time). The right-hand becomes equal to <math>\scriptstyle -\Delta V\,d\rho/dt</math>  which is the rate of decrease in mass. Hence the net flow of mass leaving the the volume &Delta;''V'' is equal to the decrease of mass in &Delta;''V'' (both per unit time).
 
If the fluid is incompressible, i.e., the mass density &rho; is constant, meaning that its time derivative is zero, the flux satisifies
:<math>
\boldsymbol{\nabla}\cdot\boldsymbol{\phi}(\mathbf{r},t) =  0.
</math>
Such a  vector field '''&phi;'''('''r''',''t'') is called ''divergence-free'', ''solenoidal'', or ''circuital''.

Revision as of 01:08, 19 July 2008

This article is developing and not approved.
Main Article
Discussion
Related Articles  [?]
Bibliography  [?]
External Links  [?]
Citable Version  [?]
 
This editable Main Article is under development and subject to a disclaimer.

The divergence of a differentiable vector field F(r) is given by the following expression,

where ex, ey, ez form an orthonormal basis of . The dot stands for a dot product.

The physical meaning of divergence is given by the continuity equation. Consider a compressible fluid (gas or liquid) that is in flow. Let φ(r,t) be its flux (mass per unit time passing through a unit surface) and let ρ(r,t) be its mass density (amount of mass per unit volume) at the same point r. The flux is a vector field (at any point a vector gives the direction of flow), and the density is a scalar field (function). The continuity equation states that

Multiply the left- and right-hand side by an infinitesimal volume element ΔV containing the point r. Then the left hand side gives the mass leaving ΔV minus the mass entering ΔV (per unit time). The right-hand becomes equal to which is the rate of decrease in mass. Hence the net flow of mass leaving the the volume ΔV is equal to the decrease of mass in ΔV (both per unit time).

If the fluid is incompressible, i.e., the mass density ρ is constant, meaning that its time derivative is zero, the flux satisifies

Such a vector field φ(r,t) is called divergence-free, solenoidal, or circuital.