Quasiorder on compact connected orientable manifolds: Difference between revisions

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* A [[connected sum]] is always ''higher'' in the quasiorder than each of the summands, whatever the ring of coefficients.
* A [[connected sum]] is always ''higher'' in the quasiorder than each of the summands, whatever the ring of coefficients.
* The <math>n</math>-sphere is the lowest in the quasiorder -- there is always a [[degree one map]] from any compact connected orientable manifold to the <math>n</math>-sphere
* The <math>n</math>-sphere is the lowest in the quasiorder -- there is always a [[degree one map]] from any compact connected orientable manifold to the <math>n</math>-sphere
==The quasiorder in two dimensions==
In two dimensions, the quasiorder is in fact a total order on the manifolds upto homeomorphism: the lowest is the sphere. The surface of genus <math>g</math> is higher in the quasiorder than the surface of genus <math>h</math> iff <math>g \ge h</math>.

Revision as of 00:55, 3 December 2007

Definition

Consider the class C of all n-dimensional compact connected orientable manifolds. Then for any ring of coefficients R, we get a quasiorder on C (dependent on R), as follows: we say that MN if there is a continuous map from M to N that induces an isomorphism on the nth homology.

When the ring R=Z, this is equivalent to demanding that, for suitable orientations of M and N, there is a degree one map from M to N.

Facts

  • A connected sum is always higher in the quasiorder than each of the summands, whatever the ring of coefficients.
  • The n-sphere is the lowest in the quasiorder -- there is always a degree one map from any compact connected orientable manifold to the n-sphere

The quasiorder in two dimensions

In two dimensions, the quasiorder is in fact a total order on the manifolds upto homeomorphism: the lowest is the sphere. The surface of genus g is higher in the quasiorder than the surface of genus h iff gh.