Pseudomanifold

In mathematics, a pseudomanifold is a special type of topological space. It looks like a manifold at most of its points, but it may contain singularities. For example, the cone of solutions of ${\displaystyle z^2=x^2+y^2}$ forms a pseudomanifold.

A pseudomanifold can be regarded as a combinatorial realisation of the general idea of a manifold with singularities. The concepts of orientability, orientation and degree of a mapping make sense for pseudomanifolds and moreover, within the combinatorial approach, pseudomanifolds form the natural domain of definition for these concepts.^[1][2]

A topological space X endowed with a triangulation K is an n-dimensional pseudomanifold if the following conditions hold:^[3]

1. (pure) Template:Nowrap is the union of all n-simplices.
2. Every Template:Nowrap is a face of exactly one or two n-simplices for n > 1.
3. For every pair of n-simplices σ and σ' in K, there is a sequence of n-simplices Template:Nowrap such that the intersection Template:Nowrap is an Template:Nowrap for all i = 0, ..., k−1.

• Condition 2 means that X is a non-branching simplicial complex.^[4]
• Condition 3 means that X is a strongly connected simplicial complex.^[4]
• If we require Condition 2 to hold only for Template:Nowrap in sequences of Template:Nowrap in Condition 3, we obtain an equivalent definition only for n=2. For n≥3 there are examples of combinatorial non-pseudomanifolds that are strongly connected through sequences of Template:Nowrap satisfying Condition 2.^[5]

Strongly connected n-complexes can always be assembled from Template:Nowrap gluing just two of them at Template:Nowrap. However, in general, construction by gluing can lead to non-pseudomanifoldness (see Figure 2).

Nevertheless it is always possible to decompose a non-pseudomanifold surface into manifold parts cutting only at singular edges and vertices (see Figure 2 in blue). For some surfaces several non-equivalent options are possible (see Figure 3).

On the other hand, in higher dimension, for n>2, the situation becomes rather tricky.

• In general, for n≥3, n-pseudomanifolds cannot be decomposed into manifold parts only by cutting at singularities (see Figure 4).

• For n≥3, there are n-complexes that cannot be decomposed, even into pseudomanifold parts, only by cutting at singularities.^[5]

• A pseudomanifold is called normal if the link of each simplex with codimension ≥ 2 is a pseudomanifold.

• A pinched torus (see Figure 1) is an example of an orientable, compact 2-dimensional pseudomanifold.^[3]

(Note that a pinched torus is not a normal pseudomanifold, since the link of a vertex is not connected.)

• Complex algebraic varieties (even with singularities) are examples of pseudomanifolds.^[4]

(Note that real algebraic varieties aren't always pseudomanifolds, since their singularities can be of codimension 1, take xy=0 for example.)

• Thom spaces of vector bundles over triangulable compact manifolds are examples of pseudomanifolds.^[4]
• Triangulable, compact, connected, homology manifolds over Z are examples of pseudomanifolds.^[4]
• Complexes obtained gluing two 4-simplices at a common tetrahedron are a proper superset of 4-pseudomanifolds used in spin foam formulation of loop quantum gravity.^[6]
• Combinatorial n-complexes defined by gluing two Template:Nowrap at a Template:Nowrap are not always n-pseudomanifolds. Gluing can induce non-pseudomanifoldness.^[5]

• Stratified space

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