normal vector field n. The small arrows represent the spatial velocity."/>
Figure 2.5 A time‐independent region
having oriented boundary and unit outward normal vector field ![bold n]()
. The small arrows represent the spatial velocity.
2.2.1 Mass Balance
Consider first the mass balance. We associate with each body a nonnegative, integrable function ![rho left-parenthesis bold x comma t right-parenthesis]()
, called the mass density. This function gives the mass contained in any region ![script upper V]()
of three‐dimensional Euclidean space as the volume integral
(2.2)![integral Underscript script upper V Endscripts rho left-parenthesis bold x comma t right-parenthesis d v comma]()
having physical dimension ![normal upper M]()
. Here, ![d v]()
denotes the element of volume integration. Since ![rho]()
is nonnegative, so is the mass. The expression (2.2) requires that ![dimension left-parenthesis rho right-parenthesis equals normal upper M normal upper L Superscript negative 3]()
.
The mass balance arises from a simple observation: The rate of change in the mass inside any region ![script upper V]()
of three‐dimensional space exactly balances the rate of movement of mass across the region's boundary. In symbols,
(2.3)![StartLayout 1st Row StartFraction d Over d t EndFraction integral Underscript script upper V Endscripts rho d v equals minus integral Underscript partial-differential script upper V Endscripts rho bold v dot bold n d a period EndLayout]()
This equation is the integral mass balance. Here, ![partial-differential script upper V]()
denotes the boundary of ![script upper V]()
; ![bold n left-parenthesis bold x comma t right-parenthesis]()
denotes the unit‐length vector field orthogonal to ![partial-differential script upper V]()
and pointing outward, as Figure 2.5 depicts; and ![d a]()
denotes the element of surface integration. We call the function ![rho bold v]()
in the integral on the right side of Eq. (2.3) the mass flux per unit area; the integrand ![rho bold v dot bold n]()
is the component of mass flux per unit area in the direction of the unit vector ![bold n]()
, that is, outward from ![script upper V]()
. The surface integral itself, together with the negative sign, is the net flux of mass inward across ![partial-differential script upper V]()
.
Often of greater utility than the integral equation (2.3) is a pointwise form of the mass balance, valid when the density and velocity are sufficiently smooth. To derive this form, consider a region ![script upper V]()
that does not change in time. In this case,
(2.4)![StartFraction d Over d t EndFraction integral Underscript script upper V Endscripts rho d v equals integral Underscript script upper V Endscripts StartFraction partial-differential rho Over partial-differential t EndFraction d v period]()
Also, by the divergence theorem,
(2.5)![minus integral Underscript partial-differential script upper V Endscripts rho bold v dot bold n d a equals minus integral Underscript script upper V Endscripts nabla dot left-parenthesis rho bold v right-parenthesis d v comma]()
where ![nabla dot]()
denotes the divergence operator. With respect to an orthonormal basis ![StartSet bold e 1 comma bold e 2 comma bold e 3 EndSet]()
,
![nabla dot left-parenthesis rho bold v right-parenthesis equals sigma-summation Underscript j equals 1 Overscript 3 Endscripts StartFraction partial-differential Over partial-differential x Subscript j Baseline EndFraction left-parenthesis rho v Subscript j Baseline right-parenthesis period]()
Applying the identities (2.4) and (2.5) to the integral mass balance (2.3) yields the equivalent equation
(2.6)![integral Underscript script upper V Endscripts left-bracket StartFraction partial-differential rho Over partial-differential t EndFraction plus nabla dot left-parenthesis rho bold v right-parenthesis right-bracket d v equals 0 comma]()
valid for any time‐independent region ![script upper V]()
.
If the integrand in Eq. (2.6) is continuous, then the integrand must vanish:
(2.7)![StartLayout 1st Row StartFraction partial-differential rho Over partial-differential t EndFraction plus nabla dot left-parenthesis rho bold v right-parenthesis equals 0 period EndLayout]()
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