Myers's theorem

Template:Short description Myers's theorem, also known as the Bonnet–Myers theorem, is a celebrated, fundamental theorem in the mathematical field of Riemannian geometry. It was discovered by Sumner Byron Myers in 1941. It asserts the following:

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In the special case of surfaces, this result was proved by Ossian Bonnet in 1855. For a surface, the Gauss, sectional, and Ricci curvatures are all the same, but Bonnet's proof easily generalizes to higher dimensions if one assumes a positive lower bound on the sectional curvature. Myers' key contribution was therefore to show that a Ricci lower bound is all that is needed to reach the same conclusion.

The conclusion of the theorem says, in particular, that the diameter of ${\displaystyle (M,g)}$ is finite. Therefore ${\displaystyle M}$ must be compact, as a closed (and hence compact) ball of finite radius in any tangent space is carried onto all of ${\displaystyle M}$ by the exponential map.

As a very particular case, this shows that any complete and noncompact smooth Einstein manifold must have nonpositive Einstein constant.

Since ${\displaystyle M}$ is connected, there exists the smooth universal covering map ${\displaystyle \pi :N\to M.}$ One may consider the pull-back metric Template:Math on ${\displaystyle N.}$ Since ${\displaystyle \pi }$ is a local isometry, Myers' theorem applies to the Riemannian manifold Template:Math and hence ${\displaystyle N}$ is compact and the covering map is finite. This implies that the fundamental group of ${\displaystyle M}$ is finite.

The conclusion of Myers' theorem says that for any ${\displaystyle p,q\in M,}$ one has Template:Math. In 1975, Shiu-Yuen Cheng proved: Template:Quote

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• Ambrose, W. A theorem of Myers. Duke Math. J. 24 (1957), 345–348.
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