Weierstrass–Enneper parameterization

In mathematics, the Weierstrass–Enneper parameterization of minimal surfaces is a classical piece of differential geometry. Alfred Enneper and Karl Weierstrass studied minimal surfaces as far back as 1863.

Let ${\displaystyle f}$ and ${\displaystyle g}$ be functions on either the entire complex plane or the unit disk, where ${\displaystyle g}$ is meromorphic and ${\displaystyle f}$ is analytic, such that wherever ${\displaystyle g}$ has a pole of order ${\displaystyle m}$, ${\displaystyle f}$ has a zero of order ${\displaystyle 2m}$ (or equivalently, such that the product ${\displaystyle f{g}^2}$ is holomorphic), and let ${\displaystyle c_1,c_2,c_3}$ be constants. Then the surface with coordinates ${\displaystyle (x_1,x_2,x_3)}$ is minimal, where the ${\displaystyle x_k}$ are defined using the real part of a complex integral, as follows: $${\displaystyle \begin{array}{rl}{x}_k(\zeta )& =\mathrm{R}\mathrm{e}\{{\displaystyle \underset{0}{\overset{\zeta }{\int }}}{\phi }_k(z)dz\}+c_k,k=1,2,3\\ {\phi }_1& =f(1-g^2)/2\\ {\phi }_2& =if(1+g^2)/2\\ {\phi }_3& =fg\end{array}}$$ The converse is also true: every nonplanar minimal surface defined over a simply connected domain can be given a parametrization of this type.^[1] For example, Enneper's surface has f(z) = 1, g(z) = z^m.

Parametric surface of complex variables

The Weierstrass-Enneper model defines a minimal surface ${\displaystyle X}$ (${\displaystyle {\mathbb{ℝ}}^3}$) on a complex plane (${\displaystyle \mathbb{ℂ}}$). Let ${\displaystyle \omega =u+vi}$ (the complex plane as the ${\displaystyle uv}$ space), the Jacobian matrix of the surface can be written as a column of complex entries: $${\displaystyle \mathbf{J}=\left[\begin{array}{c}(1-g^2(\omega ))f(\omega )\\ i(1+g^2(\omega ))f(\omega )\\ 2g(\omega )f(\omega )\end{array}\right]}$$ where ${\displaystyle f(\omega )}$ and ${\displaystyle g(\omega )}$ are holomorphic functions of ${\displaystyle \omega }$. The Jacobian ${\displaystyle \mathbf{J}}$ represents the two orthogonal tangent vectors of the surface:^[2] $${\displaystyle {\mathbf{X}}_{\mathbf{u}}=\left[\begin{array}{c}\mathrm{Re}{\mathbf{J}}_1\\ \mathrm{Re}{\mathbf{J}}_2\\ \mathrm{Re}{\mathbf{J}}_3\end{array}\right]{\mathbf{X}}_{\mathbf{v}}=\left[\begin{array}{c}-\mathrm{Im}{\mathbf{J}}_1\\ -\mathrm{Im}{\mathbf{J}}_2\\ -\mathrm{Im}{\mathbf{J}}_3\end{array}\right]}$$ The surface normal is given by $${\displaystyle \hat{\mathbf{n}}=\frac{{\mathbf{X}}_{\mathbf{u}}\times {\mathbf{X}}_{\mathbf{v}}}{|{\mathbf{X}}_{\mathbf{u}}\times {\mathbf{X}}_{\mathbf{v}}|}=\frac{1}{|g{|}^2+1}\left[\begin{array}{c}2\mathrm{Re}g\\ 2\mathrm{Im}g\\ |g{|}^2-1\end{array}\right]}$$ The Jacobian ${\displaystyle \mathbf{J}}$ leads to a number of important properties: ${\displaystyle {\mathbf{X}}_{\mathbf{u}}\cdot {\mathbf{X}}_{\mathbf{v}}=0}$, ${\displaystyle {{\mathbf{X}}_{\mathbf{u}}}^2=\mathrm{Re}({\mathbf{J}}^2)}$, ${\displaystyle {{\mathbf{X}}_{\mathbf{v}}}^2=\mathrm{Im}({\mathbf{J}}^2)}$, ${\displaystyle {\mathbf{X}}_{\mathbf{u}\mathbf{u}}+{\mathbf{X}}_{\mathbf{v}\mathbf{v}}=0}$. The proofs can be found in Sharma's essay: The Weierstrass representation always gives a minimal surface.^[3] The derivatives can be used to construct the first fundamental form matrix: $${\displaystyle \left[\begin{array}{cc}{\mathbf{X}}_{\mathbf{u}}\cdot {\mathbf{X}}_{\mathbf{u}}& {\mathbf{X}}_{\mathbf{u}}\cdot {\mathbf{X}}_{\mathbf{v}}\\ {\mathbf{X}}_{\mathbf{v}}\cdot {\mathbf{X}}_{\mathbf{u}}& {\mathbf{X}}_{\mathbf{v}}\cdot {\mathbf{X}}_{\mathbf{v}}\end{array}\right]=\left[\begin{array}{cc}1& 0\\ 0& 1\end{array}\right]}$$ and the second fundamental form matrix $${\displaystyle \left[\begin{array}{cc}{\mathbf{X}}_{\mathbf{u}\mathbf{u}}\cdot \hat{\mathbf{n}}& {\mathbf{X}}_{\mathbf{u}\mathbf{v}}\cdot \hat{\mathbf{n}}\\ {\mathbf{X}}_{\mathbf{v}\mathbf{u}}\cdot \hat{\mathbf{n}}& {\mathbf{X}}_{\mathbf{v}\mathbf{v}}\cdot \hat{\mathbf{n}}\end{array}\right]}$$ Finally, a point ${\displaystyle {\omega }_t}$ on the complex plane maps to a point ${\displaystyle \mathbf{X}}$ on the minimal surface in ${\displaystyle {\mathbb{ℝ}}^3}$ by $${\displaystyle \mathbf{X}=\left[\begin{array}{c}\mathrm{Re}{\displaystyle \underset{{\omega }_0}{\overset{{\omega }_t}{\int }}}{\mathbf{J}}_{1}d\omega \\ \mathrm{Re}{\displaystyle \underset{{\omega }_0}{\overset{{\omega }_t}{\int }}}{\mathbf{J}}_{2}d\omega \\ \mathrm{Re}{\displaystyle \underset{{\omega }_0}{\overset{{\omega }_t}{\int }}}{\mathbf{J}}_{3}d\omega \end{array}\right]}$$ where ${\displaystyle {\omega }_0=0}$ for all minimal surfaces throughout this paper except for Costa's minimal surface where ${\displaystyle {\omega }_0=(1+i)/2}$.

Embedded minimal surfaces and examples

The classical examples of embedded complete minimal surfaces in ${\displaystyle {\mathbb{ℝ}}^3}$ with finite topology include the plane, the catenoid, the helicoid, and the Costa's minimal surface. Costa's surface involves Weierstrass's elliptic function ${\displaystyle \mathrm{\wp }}$:^[4] $${\displaystyle g(\omega )=\frac{A}{{\mathrm{\wp }}^{\prime }(\omega )}}$$ $${\displaystyle f(\omega )=\mathrm{\wp }(\omega )}$$ where ${\displaystyle A}$ is a constant.^[5]

Helicatenoid

Choosing the functions ${\displaystyle f(\omega )=e^{-i\alpha }{e}^{\omega /A}}$ and ${\displaystyle g(\omega )=e^{-\omega /A}}$, a one parameter family of minimal surfaces is obtained. $${\displaystyle {\phi }_1=e^{-i\alpha }\sinh \left(\frac{\omega }{A}\right)}$$ $${\displaystyle {\phi }_2=i{e}^{-i\alpha }\cosh \left(\frac{\omega }{A}\right)}$$ $${\displaystyle {\phi }_3=e^{-i\alpha }}$$ $${\displaystyle \mathbf{X}(\omega )=\mathrm{Re}\left[\begin{array}{c}{e}^{-i\alpha }A\cosh \left(\frac{\omega }{A}\right)\\ i{e}^{-i\alpha }A\sinh \left(\frac{\omega }{A}\right)\\ e^{-i\alpha }\omega \\ \end{array}\right]=\cos (\alpha )\left[\begin{array}{c}A\cosh \left(\frac{\mathrm{Re}(\omega )}{A}\right)\cos \left(\frac{\mathrm{Im}(\omega )}{A}\right)\\ -A\cosh \left(\frac{\mathrm{Re}(\omega )}{A}\right)\sin \left(\frac{\mathrm{Im}(\omega )}{A}\right)\\ \mathrm{Re}(\omega )\\ \end{array}\right]+\sin (\alpha )\left[\begin{array}{c}A\sinh \left(\frac{\mathrm{Re}(\omega )}{A}\right)\sin \left(\frac{\mathrm{Im}(\omega )}{A}\right)\\ A\sinh \left(\frac{\mathrm{Re}(\omega )}{A}\right)\cos \left(\frac{\mathrm{Im}(\omega )}{A}\right)\\ \mathrm{Im}(\omega )\\ \end{array}\right]}$$ Choosing the parameters of the surface as ${\displaystyle \omega =s+i(A\varphi )}$: $${\displaystyle \mathbf{X}(s,\varphi )=\cos (\alpha )\left[\begin{array}{c}A\cosh \left(\frac{s}{A}\right)\cos \left(\varphi \right)\\ -A\cosh \left(\frac{s}{A}\right)\sin \left(\varphi \right)\\ s\\ \end{array}\right]+\sin (\alpha )\left[\begin{array}{c}A\sinh \left(\frac{s}{A}\right)\sin \left(\varphi \right)\\ A\sinh \left(\frac{s}{A}\right)\cos \left(\varphi \right)\\ A\varphi \\ \end{array}\right]}$$ At the extremes, the surface is a catenoid ${\displaystyle (\alpha =0)}$ or a helicoid ${\displaystyle (\alpha =\pi /2)}$. Otherwise, ${\displaystyle \alpha }$ represents a mixing angle. The resulting surface, with domain chosen to prevent self-intersection, is a catenary rotated around the ${\displaystyle {\mathbf{X}}_3}$ axis in a helical fashion.

Lines of curvature

One can rewrite each element of second fundamental matrix as a function of ${\displaystyle f}$ and ${\displaystyle g}$, for example $${\displaystyle {\mathbf{X}}_{\mathbf{u}\mathbf{u}}\cdot \hat{\mathbf{n}}=\frac{1}{|g{|}^2+1}\left[\begin{array}{c}\mathrm{Re}((1-g^2)f^{\prime }-2gf{g}^{\prime })\\ \mathrm{Re}((1+g^2)f^{\prime }i+2gf{g}^{\prime }i)\\ \mathrm{Re}(2g{f}^{\prime }+2f{g}^{\prime })\\ \end{array}\right]\cdot \left[\begin{array}{c}\mathrm{Re}\left(2g\right)\\ \mathrm{Re}(-2gi)\\ \mathrm{Re}(|g{|}^2-1)\\ \end{array}\right]=-2\mathrm{Re}(f{g}^{\prime })}$$ And consequently the second fundamental form matrix can be simplified as $${\displaystyle \left[\begin{array}{cc}-\mathrm{Re}f{g}^{\prime }& \mathrm{Im}f{g}^{\prime }\\ \mathrm{Im}f{g}^{\prime }& \mathrm{Re}f{g}^{\prime }\end{array}\right]}$$

One of its eigenvectors is $${\displaystyle \overline{\sqrt{f{g}^{\prime }}}}$$ which represents the principal direction in the complex domain.^[6] Therefore, the two principal directions in the ${\displaystyle uv}$ space turn out to be $${\displaystyle \varphi =-\frac{1}{2}\mathrm{Arg}(f{g}^{\prime })\pm k\pi /2}$$

See also

• Associate family
• Bryant surface, found by an analogous parameterization in hyperbolic space

References