6.5 Divergence and curl (Page 2/9)

Calculus volume 3 Page 2 / 9

A vector field in two dimensions with negative divergence. The arrows point in towards the origin in a radial pattern. The closer the arrows are to the origin, the larger they are. — This vector field has negative divergence.

To get a global sense of what divergence is telling us, suppose that a vector field in $ℝ^{2}$ represents the velocity of a fluid. Imagine taking an elastic circle (a circle with a shape that can be changed by the vector field) and dropping it into a fluid. If the circle maintains its exact area as it flows through the fluid, then the divergence is zero. This would occur for both vector fields in [link] . On the other hand, if the circle’s shape is distorted so that its area shrinks or expands, then the divergence is not zero. Imagine dropping such an elastic circle into the radial vector field in [link] so that the center of the circle lands at point (3, 3). The circle would flow toward the origin, and as it did so the front of the circle would travel more slowly than the back, causing the circle to “scrunch” and lose area. This is how you can see a negative divergence.

Calculating divergence at a point

If $F (x, y, z) = e^{x} i + y z j - y^{2} k,$ then find the divergence of F at $(0, 2, −1) .$

The divergence of F is

\frac{\partial}{\partial x} (e^{x}) + \frac{\partial}{\partial y} (y z) - \frac{\partial}{\partial z} (y z^{2}) = e^{x} + z - 2 y z .

Therefore, the divergence at $(0, 2, −1)$ is $e^{0} - 1 + 4 = 4 .$ If F represents the velocity of a fluid, then more fluid is flowing out than flowing in at point $(0, 2, −1) .$

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Find $div F$ for $F (x, y, z) = ⟨ x y, 5 - z^{2} y, x^{2} + y^{2} ⟩ .$

$y - z^{2}$

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One application for divergence occurs in physics, when working with magnetic fields. A magnetic field is a vector field that models the influence of electric currents and magnetic materials. Physicists use divergence in Gauss’s law for magnetism , which states that if B is a magnetic field, then $\nabla \cdot B = 0;$ in other words, the divergence of a magnetic field is zero.

Determining whether a field is magnetic

Is it possible for $F (x, y) = ⟨ x^{2} y, y - x y^{2} ⟩$ to be a magnetic field?

If F were magnetic, then its divergence would be zero. The divergence of F is

\frac{\partial}{\partial x} (x^{2} y) + \frac{\partial}{\partial y} (y - x y^{2}) = 2 x y + 1 - 2 x y = 1

and therefore F cannot model a magnetic field ( [link] ).

A vector field in two dimensions with divergence equal to 1. The arrows are quite flat near the x axis and vertical near the y axis. They seem to asymptotically approach the axes in quadrants 2 and 4, pointing up and to the right in quadrant 2 and down and to the left in quadrant 4. In quadrant 1, they start by pointing up and to the right close to the y axis, but they soon shift to pointing down and to the right. In quadrant 3, they start by pointing down and to the left close to the y axis, bu they soon shift to pointing up and to the left. The closer the arrows are to the origin, the shorter they are. — The divergence of vector field $F (x, y) = ⟨ x^{2} y, y - x y^{2} ⟩$ is one, so it cannot model a magnetic field.

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Another application for divergence is detecting whether a field is source free. Recall that a source-free field is a vector field that has a stream function; equivalently, a source-free field is a field with a flux that is zero along any closed curve. The next two theorems say that, under certain conditions, source-free vector fields are precisely the vector fields with zero divergence.

Divergence of a source-free vector field

If $F = ⟨ P, Q ⟩$ is a source-free continuous vector field with differentiable component functions, then $div F = 0 .$

Proof

Since F is source free, there is a function $g (x, y)$ with $g_{y} = P$ and $− g_{x} = Q .$ Therefore, $F = ⟨ g_{y}, − g_{x} ⟩$ and $div F = g_{y x} - g_{x y} = 0$ by Clairaut’s theorem.

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The converse of [link] is true on simply connected regions, but the proof is too technical to include here. Thus, we have the following theorem, which can test whether a vector field in $ℝ^{2}$ is source free.

Divergence test for source-free vector fields

Let $F = ⟨ P, Q ⟩$ be a continuous vector field with differentiable component functions with a domain that is simply connected. Then, $div F = 0$ if and only if F is source free.

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Source: OpenStax, Calculus volume 3. OpenStax CNX. Feb 05, 2016 Download for free at http://legacy.cnx.org/content/col11966/1.2

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