Cartan–Ambrose–Hicks theorem explained

In mathematics, the Cartan–Ambrose–Hicks theorem is a theorem of Riemannian geometry, according to which the Riemannian metric is locally determined by the Riemann curvature tensor, or in other words, behavior of the curvature tensor under parallel translation determines the metric.

The theorem is named after Élie Cartan, Warren Ambrose, and his PhD student Noel Hicks.^[1] Cartan proved the local version. Ambrose proved a global version that allows for isometries between general Riemannian manifolds with varying curvature, in 1956.^[2] This was further generalized by Hicks to general manifolds with affine connections in their tangent bundles, in 1959.^[3]

A statement and proof of the theorem can be found in ^[4]

Introduction

Let

M,N

be connected, complete Riemannian manifolds. We consider the problem of isometrically mapping a small patch on

to a small patch on

Let

x\inM,y\inN

, and let

I:T_{xM →}T_yN

be a linear isometry. This can be interpreted as isometrically mapping an infinitesimal patch (the tangent space) at

to an infinitesimal patch at

. Now we attempt to extend it to a finite (rather than infinitesimal) patch.

For sufficiently small

r>0

, the exponential maps

\exp_x:B_r(x)\subsetT_{xM →}M,\exp_y:B_r(y)\subsetT_{yN →}N

are local diffeomorphisms. Here,

B_r(x)

is the ball centered on

of radius

One then defines a diffeomorphism

f:B_{r(x) →}B_r(y)

f=\exp_y\circI\circ

	-1
\exp
	x

When is

an isometry? Intuitively, it should be an isometry if it satisfies the two conditions:

It is a linear isometry at the tangent space of every point on

B_r(x)

, that is, it is an isometry on the infinitesimal patches.

It preserves the curvature tensor at the tangent space of every point on

B_r(x)

, that is, it preserves how the infinitesimal patches fit together.

is an isometry, it must preserve the geodesics. Thus, it is natural to consider the behavior of

as we transport it along an arbitrary geodesic radius

\gamma:\left[0,T\right] → B_r(x)\subsetM

starting at

\gamma(0)=x

. By property of the exponential mapping,

maps it to a geodesic radius of

B_r(y)

starting at

f(\gamma)(0)=y

Let

P_\gamma(t)

be the parallel transport along

\gamma

(defined by the Levi-Civita connection), and

P_f(\gamma)(t)

be the parallel transport along

f(\gamma)

, then we have the mapping between infinitesimal patches along the two geodesic radii:

I_\gamma(t)=P_f(\gamma)(t)\circI\circ

	-1
P
	\gamma(t)

:T_\gamma(t)M → T_f(\gamma(t))N forallt\in[0,T]

Cartan's theorem

The original theorem proven by Cartan is the local version of the Cartan–Ambrose–Hicks theorem.

f

is an isometry if and only if for all geodesic radii
\gamma:\left[0,T\right] → B_r(x)\subsetM

with
\gamma(0)=x

, and all
t\in[0,T],X,Y,Z\inT_\gamma(t)M

, we have
I_\gamma(t)(R(X,Y,Z))=\overline{R}(I_\gamma(t)(X),I_{\gamma(t)(Y),}I_\gamma(t)(Z))

where

R,\overline{R}

are Riemann curvature tensors of
M,N

.

In words, it states that

is an isometry if and only if the only way to preserve its infinitesimal isometry also preserves the Riemannian curvature.

Note that

generally does not have to be a diffeomorphism, but only a locally isometric covering map. However,

must be a global isometry if

is simply connected.

Cartan–Ambrose–Hicks theorem

Theorem: For Riemann curvature tensors

R,\overline{R}

and all broken geodesics (a broken geodesic is a curve that is piecewise geodesic)

\gamma:\left[0,T\right] → M

with

\gamma(0)=x

, suppose that

I_{\gamma(t)(R(X,Y,Z))=\overline{R}(I}_{\gamma(t)(X),}I_{\gamma(t)(Y),}I_{\gamma(t)(Z))}

for all

t\in[0,T],X,Y,Z\inT_\gamma(t)M

Then, if two broken geodesics beginning at

have the same endpoint, the corresponding broken geodesics (mapped by

I_\gamma

) in

also have the same end point. Consequently, there exists a map

F:M → N

definedby mapping the broken geodesic endpoints in

to the corresponding geodesic endpoints in

The map

F:M → N

is a locally isometric covering map.

is also simply connected, then

is an isometry.

Locally symmetric spaces

A Riemannian manifold is called locally symmetric if its Riemann curvature tensor is invariant under parallel transport:

\nablaR=0.

A simply connected Riemannian manifold is locally symmetric if it is a symmetric space.

From the Cartan–Ambrose–Hicks theorem, we have:

Theorem: Let

M,N

be connected, complete, locally symmetric Riemannian manifolds, and let

be simply connected. Let their Riemann curvature tensors be

R,\overline{R}

. Let

x\inM,y\inN

and

I:T_{xM →}T_yN

be a linear isometry with

I(R(X,Y,Z))=\overline{R}(I(X),I(Y),I(Z))

. Then there exists a locally isometric covering map

F:M → N

with

F(x)=y

and

D_xF=I

Corollary: Any complete locally symmetric space is of the form

M/\Gamma

, where

is a symmetric space and

\Gamma\subsetIsom(M)

is a discrete subgroup of isometries of

Classification of space forms

\in\{+1,0,-1\}

is respectively isometric to the n-sphere

Sⁿ

, the n-Euclidean space

Eⁿ

, and the n-hyperbolic space

Hⁿ

Notes and References

https://www.genealogy.math.ndsu.nodak.edu/id.php?id=7688 Mathematics Genealogy Project
Ambrose. W.. 1956. Parallel Translation of Riemannian Curvature. The Annals of Mathematics. JSTOR. 64. 2. 337. 10.2307/1969978. 0003-486X.
Hicks. Noel. 1959. A theorem on affine connexions. Illinois Journal of Mathematics. 3. 2. 242–254. 10.1215/ijm/1255455125. 0019-2082. free.
Book: Cheeger, Jeff. Comparison theorems in Riemannian geometry. Ebin. David G.. AMS Chelsea Pub. 2008. 0-8218-4417-2. Providence, R.I. Chapter 1, Section 12, The Cartan–Ambrose–Hicks Theorem. 185095562.