Kelvin-Stokes Theorem

Theorem
Let $S$ be some orientable smooth surface with boundary in $\R^3$.

Let $\mathbf F:\R^3 \to \R^3$ be a vector-valued function with Euclidean coordinate expression:
 * $F = f_1 \mathbf i + f_2 \mathbf j + f_3 \mathbf k$

where $f_i: \R^3 \to \R$.

Then:
 * $\displaystyle \oint_{\partial S} f_1 \ \mathrm d x + f_2 \ \mathrm d y + f_3 \ \mathrm d z = \iint_S \left({\nabla \times \mathbf F}\right) \cdot \mathbf n \ \mathrm d A$

where $\mathbf n$ is the unit normal to $S$ and $\mathrm d A$ is the area element on the surface.

Proof
Let $\mathbf r:\R^2 \to \R^3, \mathbf r \left({s, t}\right)$ be a smooth parametrization of $S$ from some region $R$ in the $st$-plane, so that:
 * $\mathbf r \left({R}\right) = S$

and:
 * $\mathbf r \left({\partial R}\right) = \partial S$

First, we convert the left hand side into a line integral:

so that if we define:
 * $\mathbf G = \left({G_1, G_2}\right) = \left({\mathbf F \cdot \dfrac{\partial \mathbf r}{\partial s}, \mathbf F \cdot \dfrac{\partial \mathbf r} {\partial t} }\right)$

then:


 * $\displaystyle \int_{\partial S} \mathbf F \cdot \ \mathrm d \mathbf r = \int_{\partial R} \mathbf G \cdot \ \mathrm d \mathbf s$

where $\mathbf s$ is the position vector in the $s t$-plane.

Note that:


 * $\frac{\partial G_2}{\partial s} = \mathbf F \cdot \frac{\partial}{\partial s} \paren {\frac{\partial \mathbf r}{\partial t}}

+ \frac{\partial \mathbf r}{\partial t} \cdot \frac{\partial \mathbf F}{\partial s}$ by derivative of Dot Product


 * $\frac{\partial G_1}{\partial t} = \mathbf F \cdot \frac{\partial}{\partial t} \paren {\frac{\partial \mathbf r}{\partial s}}

+ \frac{\partial \mathbf r}{\partial s} \cdot \frac{\partial \mathbf F}{\partial t}$ by Derivative of Dot Product

Symmetry of second derivatives

We turn now to the right-hand expression and write it in terms of $s$ and $t$:

By Green's Theorem, this can be written as:


 * $\displaystyle \int_{\partial R} \mathbf G \cdot \ \mathrm d \mathbf s$

Hence both sides of the theorem equation are equal.

Also known as
Also known as the Classical Stokes' Theorem.