In mathematics, the mean curvature
H
S
The concept was used by Sophie Germain in her work on elasticity theory.[1] [2] Jean Baptiste Marie Meusnier used it in 1776, in his studies of minimal surfaces. It is important in the analysis of minimal surfaces, which have mean curvature zero, and in the analysis of physical interfaces between fluids (such as soap films) which, for example, have constant mean curvature in static flows, by the Young–Laplace equation.
Let
p
S
p
S
S
\theta
\kappa1
\kappa2
S
The mean curvature at
p\inS
\theta
H=
| 1 | |
| 2\pi |
| 2\pi | |
| \int | |
| 0 |
\kappa(\theta) d\theta
By applying Euler's theorem, this is equal to the average of the principal curvatures :
H={1\over2}(\kappa1+\kappa2).
T
| H= | 1 |
| n |
| n | |
| \sum | |
| i=1 |
\kappai.
More abstractly, the mean curvature is the trace of the second fundamental form divided by n (or equivalently, the shape operator).
Additionally, the mean curvature
H
\nabla
H\vec{n}=gij\nablai\nablajX,
X(x)
\vec{n}
gij
A surface is a minimal surface if and only if the mean curvature is zero. Furthermore, a surface which evolves under the mean curvature of the surface
S
The sphere is the only embedded surface of constant positive mean curvature without boundary or singularities. However, the result is not true when the condition "embedded surface" is weakened to "immersed surface".[3]
For a surface defined in 3D space, the mean curvature is related to a unit normal of the surface:
2H=-\nabla ⋅ \hatn
2H=Trace((II)(I-1))
If
S(x,y)
u,v
E=I(u,u)
F=I(u,v)
G=I(v,v)
l=II(u,u)
m=II(u,v)
n=II(v,v)
For the special case of a surface defined as a function of two coordinates, e.g.
z=S(x,y)
\begin{align} 2H&=-\nabla ⋅ \left(
| \nabla(z-S) | |
| |\nabla(z-S)| |
\right)\\ &=\nabla ⋅ \left(
| \nablaS-\nablaz | |
| \sqrt{1+|\nablaS|2 |
In particular at a point where
\nablaS=0
S
If the surface is additionally known to be axisymmetric with
z=S(r)
2H=
| |||||
|
+{
| \partialS | |
| \partialr |
where
| { | \partialS |
| \partialr |
The mean curvature of a surface specified by an equation
F(x,y,z)=0
\nablaF=\left(
| \partialF | |
| \partialx |
,
| \partialF | |
| \partialy |
,
| \partialF | |
| \partialz |
\right)
| styleHess(F)= \begin{pmatrix} | \partial2F |
| \partialx2 |
&
| \partial2F | |
| \partialx\partialy |
&
| \partial2F | \\ | |
| \partialx\partialz |
| \partial2F | |
| \partialy\partialx |
&
| \partial2F | |
| \partialy2 |
&
| \partial2F | \\ | |
| \partialy\partialz |
| \partial2F | |
| \partialz\partialx |
&
| \partial2F | |
| \partialz\partialy |
&
| \partial2F | |
| \partialz2 |
\end{pmatrix} .
H=
| \nablaF Hess(F) \nablaFT-|\nablaF|2Trace(Hess(F)) | |
| 2|\nablaF|3 |
Another form is as the divergence of the unit normal. A unit normal is given by
| \nablaF | |
| |\nablaF| |
H=-{
| 1 | |
| 2 |
An alternate definition is occasionally used in fluid mechanics to avoid factors of two:
Hf=(\kappa1+\kappa2)
This results in the pressure according to the Young–Laplace equation inside an equilibrium spherical droplet being surface tension times
Hf
\kappa1=\kappa2=r-1
See main article: Minimal surface. A minimal surface is a surface which has zero mean curvature at all points. Classic examples include the catenoid, helicoid and Enneper surface. Recent discoveries include Costa's minimal surface and the Gyroid.
See main article: Constant-mean-curvature surface. An extension of the idea of a minimal surface are surfaces of constant mean curvature. The surfaces of unit constant mean curvature in hyperbolic space are called Bryant surfaces.[7]