In mathematics, a quasitoric manifold is a topological analogue of the nonsingular projective toric variety of algebraic geometry. A smooth -dimensional manifold is a quasitoric manifold if it admits a smooth, locally standard action of an -dimensional torus, with orbit space an -dimensional simple convex polytope.

Quasitoric manifolds were introduced in 1991 by M. Davis and T. Januszkiewicz,[1] who called them "toric manifolds". However, the term "quasitoric manifold" was eventually adopted to avoid confusion with the class of compact smooth toric varieties, which are known to algebraic geometers as toric manifolds.[2]

Quasitoric manifolds are studied in a variety of contexts in algebraic topology, such as complex cobordism theory, and the other oriented cohomology theories.[3]

Definitions

edit

Denote the  -th subcircle of the  -torus   by   so that  . Then coordinate-wise multiplication of   on   is called the standard representation.

Given open sets   in   and   in  , that are closed under the action of  , a  -action on   is defined to be locally isomorphic to the standard representation if  , for all   in  ,   in  , where   is a homeomorphism  , and   is an automorphism of  .

Given a simple convex polytope   with   facets, a  -manifold   is a quasitoric manifold over   if,

  1. the  -action is locally isomorphic to the standard representation,
  2. there is a projection   that maps each  -dimensional orbit to a point in the interior of an  -dimensional face of  , for Failed to parse (SVG (MathML can be enabled via browser plugin): Invalid response ("Math extension cannot connect to Restbase.") from server "http://localhost:6011/en.wikipedia.org/v1/":): {\displaystyle l = 0,}    .

The definition implies that the fixed points of   under the  -action are mapped to the vertices of   by  , while points where the action is free project to the interior of the polytope.

The dicharacteristic function

edit

A quasitoric manifold can be described in terms of a dicharacteristic function and an associated dicharacteristic matrix. In this setting it is useful to assume that the facets   of   are ordered so that the intersection   is a vertex   of  , called the initial vertex.

A dicharacteristic function is a homomorphism  , such that if   is a codimension-  face of  , then   is a monomorphism on restriction to the subtorus   in  .

The restriction of λ to the subtorus   corresponding to the initial vertex   is an isomorphism, and so   can be taken to be a basis for the Lie algebra of  . The epimorphism of Lie algebras associated to λ may be described as a linear transformation  , represented by the   dicharacteristic matrix   given by

 

The  th column of   is a primitive vector   in  , called the facet vector. As each facet vector is primitive, whenever the facets   meet in a vertex, the corresponding columns   form a basis of  , with determinant equal to  . The isotropy subgroup associated to each facet   is described by

 

for some   in  .

In their original treatment of quasitoric manifolds, Davis and Januskiewicz[1] introduced the notion of a characteristic function that mapped each facet of the polytope to a vector determining the isotropy subgroup of the facet, but this is only defined up to sign. In more recent studies of quasitoric manifolds, this ambiguity has been removed by the introduction of the dicharacteristic function and its insistence that each circle   be oriented, forcing a choice of sign for each vector  . The notion of the dicharacteristic function was originally introduced V. Buchstaber and N. Ray[4] to enable the study of quasitoric manifolds in complex cobordism theory. This was further refined by introducing the ordering of the facets of the polytope to define the initial vertex, which eventually leads to the above neat representation of the dicharacteristic matrix   as  , where   is the identity matrix and   is an   submatrix.[5]

Relation to the moment-angle complex

edit

The kernel   of the dicharacteristic function acts freely on the moment angle complex  , and so defines a principal  -bundle   over the resulting quotient space  . This quotient space can be viewed as

 

where pairs  ,   of   are identified if and only if   and   is in the image of   on restriction to the subtorus   that corresponds to the unique face   of   containing the point  , for some  .

It can be shown that any quasitoric manifold   over   is equivariently diffeomorphic to a quasitoric manifold of the form of the quotient space above.[6]

Examples

edit
  • The  -dimensional complex projective space   is a quasitoric manifold over the  -simplex  . If   is embedded in   so that the origin is the initial vertex, a dicharacteristic function can be chosen so that the associated dicharacteristic matrix is
 

The moment angle complex   is the  -sphere  , the kernel   is the diagonal subgroup  , so the quotient of   under the action of   is  .[7]

  • The Bott manifolds that form the stages in a Bott tower are quasitoric manifolds over  -cubes. The  -cube   is embedded in   so that the origin is the initial vertex, and a dicharacteristic function is chosen so that the associated dicharacteristic matrix   has   given by
 

for integers  .

The moment angle complex   is a product of   copies of 3-sphere embedded in  , the kernel   is given by

 ,

so that the quotient of   under the action of   is the  -th stage of a Bott tower.[8] The integer values   are the tensor powers of the line bundles whose product is used in the iterated sphere-bundle construction of the Bott tower.[9]

The cohomology ring of a quasitoric manifold

edit

Canonical complex line bundles   over   given by

 ,

can be associated with each facet   of  , for  , where   acts on  , by the restriction of   to the  -th subcircle of   embedded in  . These bundles are known as the facial bundles associated to the quasitoric manifold. By the definition of  , the preimage of a facet   is a  -dimensional quasitoric facial submanifold   over  , whose isotropy subgroup is the restriction of   on the subcircle   of  . Restriction of   to   gives the normal 2-plane bundle of the embedding of   in  .

Let   in   denote the first Chern class of  . The integral cohomology ring   is generated by  , for  , subject to two sets of relations. The first are the relations generated by the Stanley–Reisner ideal of  ; linear relations determined by the dicharacterstic function comprise the second set:

 .

Therefore only   are required to generate   multiplicatively.[1]

Comparison with toric manifolds

edit
  • Any projective toric manifold is a quasitoric manifold, and in some cases non-projective toric manifolds are also quasitoric manifolds.
  • Not all quasitoric manifolds are toric manifolds. For example, the connected sum   can be constructed as a quasitoric manifold, but it is not a toric manifold.[10]

Notes

edit
  1. ^ a b c M. Davis and T. Januskiewicz, 1991.
  2. ^ V. Buchstaber and T. Panov, 2002.
  3. ^ V. Buchstaber and N. Ray, 2008.
  4. ^ V. Buchstaber and N. Ray, 2001.
  5. ^ V. Buchstaber, T. Panov and N. Ray, 2007.
  6. ^ M. Davis and T. Januskiewicz, 1991, Proposition 1.8.
  7. ^ V. Buchstaber, T. Panov and N. Ray, 2007, Example 3.11.
  8. ^ V. Buchstaber, T. Panov and N. Ray, 2007, Example 3.12.
  9. ^ Y. Civan and N. Ray, 2005.
  10. ^ M. Masuda and D. Y. Suh 2007.

References

edit
  • Buchstaber, V.; Panov, T. (2002), Torus Actions and their Applications in Topology and Combinatorics, University Lecture Series, vol. 24, American Mathematical Society
  • Buchstaber, V.; Panov, T.; Ray, N. (2007), "Spaces of polytopes and cobordism of quasitoric manifolds", Moscow Mathematical Journal, 7 (2): 219–242, arXiv:math/0609346, doi:10.17323/1609-4514-2007-7-2-219-242, S2CID 72554
  • Buchstaber, V.; Ray, N. (2001), "Tangential structures on toric manifolds and connected sums of polytopes", International Mathematics Research Notices, 2001 (4): 193–219, doi:10.1155/S1073792801000125, S2CID 8030669
  • Buchstaber, V.; Ray, N. (2008), "An Invitation to Toric Topology: Vertex Four of a Remarkable Tetrahedron", Proceedings of the International Conference in Toric Topology; Osaka City University 2006, Contemporary Mathematics, vol. 460, American Mathematical Society, pp. 1–27
  • Civan, Y.; Ray, N. (2005), "Homotopy decompositions and K-theory of Bott towers", K-Theory, 34: 1–33, arXiv:math/0408261, doi:10.1007/s10977-005-1551-x, S2CID 15934494
  • Davis, M.; Januskiewicz, T. (1991), "Convex polytopes, Coxeter orbifolds and torus actions", Duke Mathematical Journal, 62 (2): 417–451, doi:10.1215/s0012-7094-91-06217-4, S2CID 115132549
  • Masuda, M.; Suh, D. Y. (2008), "Classification problems of toric manifolds via topology", Proceedings of the International Conference in Toric Topology; Osaka City University 2006, Contemporary Mathematics, vol. 460, American Mathematical Society, pp. 273–286