# On gauge groups over high dimensional manifolds and self-equivalences of   $H$-spaces

**Authors:** Ingrid Membrillo-Solis

arXiv: 1904.12298 · 2019-04-30

## TL;DR

This paper constructs a subgroup of self-equivalences of product spaces with a matrix group structure, classifies principal bundles over complex manifolds, and uses these to decompose and classify gauge groups of certain 7-manifolds.

## Contribution

It introduces a matrix-structured subgroup of self-equivalences for homotopy commutative H-groups and applies it to classify and decompose gauge groups over high-dimensional manifolds.

## Key findings

- The subgroup _{	ext{Mat}}(Y^r) is isomorphic to GL_r( Z) or GL_r( Z_d).
- Homotopy decompositions of gauge groups are obtained for complex manifolds.
- A classification of gauge groups of principal SU(2)-bundles over specific 7-manifolds is provided.

## Abstract

Let $Y$ be a pointed space and let $\mathcal E(Y^r)$ be the group of based self-equivalences of $Y^r$, $r\geq 2$. For $Y$ a homotopy commutative $H$-group we construct a subgroup $\mathcal E_{\mathrm{Mat}}(Y^r)$ of $\mathcal E(Y^r)$ which has a group structure isomorphic to either $GL_r(\mathbb Z)$, or $GL_r(\mathbb Z_d)$, $d\geq 2$. We classify principal bundles over connected sums of $q$-sphere bundles over $n$-spheres and use the group $\mathcal E_{\mathrm{Mat}}(Y^r)$ to obtain homotopy decompositions of their gauge groups. Using these decompositions we give an integral classification, up to homotopy, of the gauge groups of principal $SU(2)$-bundles over certain 2-connected 7-manifolds with torsion-free homology.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1904.12298/full.md

## References

22 references — full list in the complete paper: https://tomesphere.com/paper/1904.12298/full.md

---
Source: https://tomesphere.com/paper/1904.12298