What is Continuity equation: Definition and 87 Discussions

A continuity equation or transport equation is an equation that describes the transport of some quantity. It is particularly simple and powerful when applied to a conserved quantity, but it can be generalized to apply to any extensive quantity. Since mass, energy, momentum, electric charge and other natural quantities are conserved under their respective appropriate conditions, a variety of physical phenomena may be described using continuity equations.
Continuity equations are a stronger, local form of conservation laws. For example, a weak version of the law of conservation of energy states that energy can neither be created nor destroyed—i.e., the total amount of energy in the universe is fixed. This statement does not rule out the possibility that a quantity of energy could disappear from one point while simultaneously appearing at another point. A stronger statement is that energy is locally conserved: energy can neither be created nor destroyed, nor can it "teleport" from one place to another—it can only move by a continuous flow. A continuity equation is the mathematical way to express this kind of statement. For example, the continuity equation for electric charge states that the amount of electric charge in any volume of space can only change by the amount of electric current flowing into or out of that volume through its boundaries.
Continuity equations more generally can include "source" and "sink" terms, which allow them to describe quantities that are often but not always conserved, such as the density of a molecular species which can be created or destroyed by chemical reactions. In an everyday example, there is a continuity equation for the number of people alive; it has a "source term" to account for people being born, and a "sink term" to account for people dying.
Any continuity equation can be expressed in an "integral form" (in terms of a flux integral), which applies to any finite region, or in a "differential form" (in terms of the divergence operator) which applies at a point.
Continuity equations underlie more specific transport equations such as the convection–diffusion equation, Boltzmann transport equation, and Navier–Stokes equations.
Flows governed by continuity equations can be visualized using a Sankey diagram.

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  1. A

    Momentum and continuity equation

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  2. A

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  3. B

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    Why is partial derivative with respect to time used in the continuity equation, \frac{\partial \rho}{\partial t} = - \nabla \vec{j} If this equation is really derived from the equation, \frac{dq}{dt} = - \int\int \vec{j} \cdot d\vec{a} Then should it be a total derivative with...
  4. D

    Continuity equation equalling a complex number

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  5. M

    Ostensible Contradiction b/w Continuity & Cartan's Magic Formula

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  6. T

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  7. L

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  8. X

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  10. S

    Macroscopic vs. microscopic continuity equation

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  11. Phrak

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  12. E

    Differentiating the Integral Form of the Continuity Equation for Fluids

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  13. S

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  14. D

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  15. T

    Proving Continuity Equation for Complex V

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  16. N

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  17. J

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  18. Shackleford

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  19. L

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  20. M

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  21. T

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  22. T

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  23. N

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  24. M

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  25. J

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  26. G

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  27. T

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  28. R

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  29. P

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  30. A

    What is the physical meaning of the continuity equation

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  31. J

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  32. A

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  33. Repetit

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  34. S

    Liquids involving continuity equation

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  35. T

    Deriving the 4d continuity equation

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  36. K

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  37. Clausius2

    What is the solution for the Continuity Equation at r=0?

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