482 B. OTHER ASPECTS OF RICCI FLOW AND RELATED FLOWS2. The mean curvature fl.ow
In this section we give a brief introduction to the mean curvature flow
and some monotonicity formulas. It is interesting to compare these mono-
tonicity formulas for the mean curvature flow to those for the Ricci flow.
We also refer the reader to the books by Ecker [132] and X.-P. Zhu [386].2.1. Mean curvature fl.ow of hypersurfaces in Riemannian man-ifolds. Let (pn+l, gp) be an orientable Riemannian manifold and let Mn
be an orientable differentiable manifold. The first fundamental form of an
embedded hypersurface X : M --> P is defined by
g (V, W) ~ gp (V, W)for V, W E TxX (M). More generally, for an immersed hypersurface, we
define
g(V, W) ~ (X*V,X*W)
for V, W E TpM. Let v denote the choice of a smooth unit normal vectorfield to M. The second fundamental form is defined by
h (V, W) ~ (Dvv, W) = -(DvW, v)
for V, WE TxX (M), where D denotes the Riemannian covariant derivative
of (P, gp) and ( , ) ~ gp ( , ). To get the second equality in the line above,
we extend W to a tangent vector field in a neighborhood of x and use
(v, W) = 0. In particular, 0 = V (v, W) = (Dvv, W) + (DvW, v). The
mean curvature is the trace of the second fundamental form:
n
H~ Lh(ei,ei),
i=lwhere { ei} is an orthonormal frame on X (M).
A time-dependent immersion Xt = X (·, t) : M --> P, t E [O, T), is
a solution of the mean curvature fl.ow (MCF) of a hypersurface in a
Riemannian manifold if
ax ~
(B.11) fit (p, t) = H (x (p, t)) ~ -H (p, t) · v (p, t), p EM, t E [O, T),where ff is called the mean curvature vector. When the Xt are embed-
dings, we define Mt ~ Xt (M). From now on we shall assume that the Xt
are embeddings, although for the most part, the following discussion holds
for immersed hypersurfaces.
Let {xi} ~=l denote local coordinates on M so that { ~-;; } are local
coordinates on Mt. We have9ij ~ g ( ~~' ~~) = ( ~~' ~~) '
hij ~ h (
88
~,
88~) = jaa~,Daxv) =-/Dax
88
~,v).
Xi xJ \ Xi DxJ \ axi xJ