Hilbert's theorem (differential geometry) explained
of constant negative
gaussian curvature
immersed in
. This theorem answers the question for the negative case of which surfaces in
can be obtained by isometrically immersing
complete manifolds with
constant curvature.
History
- Hilbert's theorem was first treated by David Hilbert in "Über Flächen von konstanter Krümmung" (Trans. Amer. Math. Soc. 2 (1901), 87–99).
- A different proof was given shortly after by E. Holmgren in "Sur les surfaces à courbure constante négative" (1902).
- A far-leading generalization was obtained by Nikolai Efimov in 1975.[1]
Proof
\varphi=\psi\circ\expp:S'\longrightarrowR3
of a plane
to the real space
. This proof is basically the same as in Hilbert's paper, although based in the books of
Do Carmo and
Spivak.
Observations: In order to have a more manageable treatment, but without loss of generality, the curvature may be considered equal to minus one,
. There is no loss of generality, since it is being dealt with constant curvatures, and similarities of
multiply
by a constant. The
exponential map \expp:Tp(S)\longrightarrowS
is a
local diffeomorphism (in fact a covering map, by Cartan-Hadamard theorem), therefore, it induces an
inner product in the
tangent space of
at
:
. Furthermore,
denotes the geometric surface
with this inner product. If
is an isometric immersion, the same holds for
\varphi=\psi\circ\expo:S'\longrightarrowR3
.
The first lemma is independent from the other ones, and will be used at the end as the counter statement to reject the results from the other lemmas.
Lemma 1: The area of
is infinite.
Proof's Sketch: The idea of the proof is to create a global isometry between
and
. Then, since
has an infinite area,
will have it too.
The fact that the
hyperbolic plane
has an infinite area comes by computing the
surface integral with the corresponding
coefficients of the
First fundamental form. To obtain these ones, the hyperbolic plane can be defined as the plane with the following inner product around a point
with coordinates
E=\left\langle
,
\right\rangle=1 F=\left\langle
,
\right\rangle=\left\langle
,
\right\rangle=0 G=\left\langle
,
\right\rangle=eu
Since the hyperbolic plane is unbounded, the limits of the integral are infinite, and the area can be calculated through
Next it is needed to create a map, which will show that the global information from the hyperbolic plane can be transfer to the surface
, i.e. a global isometry.
will be the map, whose domain is the hyperbolic plane and image the 2-dimensional manifold
, which carries the inner product from the surface
with negative curvature.
will be defined via the exponential map, its inverse, and a linear isometry between their tangent spaces,
.
That is
\varphi=\expp'\circ\psi\circ
,
where
. That is to say, the starting point
goes to the tangent plane from
through the inverse of the exponential map. Then travels from one tangent plane to the other through the isometry
, and then down to the surface
with another exponential map.
The following step involves the use of polar coordinates,
and
, around
and
respectively. The requirement will be that the axis are mapped to each other, that is
goes to
. Then
preserves the first fundamental form.
In a geodesic polar system, the
Gaussian curvature
can be expressed as
}.
In addition K is constant and fulfills the following differential equation
(\sqrt{G})\rho+K ⋅ \sqrt{G}=0
Since
and
have the same constant Gaussian curvature, then they are locally isometric (Minding's Theorem). That means that
is a local isometry between
and
. Furthermore, from the Hadamard's theorem it follows that
is also a covering map.
Since
is simply connected,
is a homeomorphism, and hence, a (global) isometry. Therefore,
and
are globally isometric, and because
has an infinite area, then
has an infinite area, as well.
Lemma 2: For each
exists a parametrization
x:U\subsetR2\longrightarrowS', p\inx(U)
, such that the coordinate curves of
are asymptotic curves of
and form a Tchebyshef net.
Lemma 3: Let
be a coordinate
neighborhood of
such that the coordinate curves are asymptotic curves in
. Then the area A of any quadrilateral formed by the coordinate curves is smaller than
.
The next goal is to show that
is a parametrization of
.
Lemma 4: For a fixed
, the curve
, is an asymptotic curve with
as arc length.
Lemma 5:
is a local diffeomorphism.
Lemma 6:
is
surjective.
Lemma 7: On
there are two differentiable linearly independent vector fields which are tangent to the
asymptotic curves of
.
Lemma 8:
is
injective.
with negative curvature exists:
As stated in the observations, the tangent plane
is endowed with the metric induced by the exponential map
\expp:Tp(S)\longrightarrowS
. Moreover,
\varphi=\psi\circ\expp:S'\longrightarrowR3
is an isometric immersion and Lemmas 5,6, and 8 show the existence of a parametrization
of the whole
, such that the coordinate curves of
are the asymptotic curves of
. This result was provided by Lemma 4. Therefore,
can be covered by a union of "coordinate" quadrilaterals
with
. By Lemma 3, the area of each quadrilateral is smaller than
. On the other hand, by Lemma 1, the area of
is infinite, therefore has no bounds. This is a contradiction and the proof is concluded.
See also
- Nash embedding theorem, states that every Riemannian manifold can be isometrically embedded into some Euclidean space.
References
- , Differential Geometry of Curves and Surfaces, Prentice Hall, 1976.
- , A Comprehensive Introduction to Differential Geometry, Publish or Perish, 1999.
Notes and References
- Ефимов, Н. В. Непогружаемость полуплоскости Лобачевского. Вестн. МГУ. Сер. мат., мех. — 1975. — No 2. — С. 83—86.
