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Fusion systems with Benson-Solomon components

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 Added by Justin Lynd
 Publication date 2018
  fields
and research's language is English




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The Benson-Solomon systems comprise a one-parameter family of simple exotic fusion systems at the prime $2$. The results we prove give significant additional evidence that these are the only simple exotic $2$-fusion systems, as conjectured by Solomon. We consider a saturated fusion system $mathcal{F}$ having an involution centralizer with a component $mathcal{C}$ isomorphic to a Benson-Solomon fusion system, and we show under rather general hypotheses that $mathcal{F}$ cannot be simple. Furthermore, we prove that if $mathcal{F}$ is almost simple with these properties, then $mathcal{F}$ is isomorphic to the next larger Benson-Solomon system extended by a group of field automorphisms. Our results are situated within Aschbachers program to provide a new proof of a major part of the classification of finite simple groups via fusion systems. One of the most important steps in this program is a proof of Walters Theorem for fusion systems, and our first result is specifically tailored for use in the proof of that step. We then apply Walters Theorem to treat the general Benson-Solomon component problem under the assumption that each component of an involution centralizer in $mathcal{F}$ is on the list of currently known quasisimple $2$-fusion systems.



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125 - Ellen Henke , Justin Lynd 2017
The Benson-Solomon systems comprise the only known family of simple saturated fusion systems at the prime two that do not arise as the fusion system of any finite group. We determine the automorphism groups and the possible almost simple extensions of these systems and of their centric linking systems.
Linking systems were introduced to provide algebraic models for $p$-completed classifying spaces of fusion systems. Every linking system over a saturated fusion system $mathcal{F}$ corresponds to a group-like structure called a locality. Given such a locality $mathcal{L}$, we prove that there is a one-to-one correspondence between the partial normal subgroups of $mathcal{L}$ and the normal subsystems of the fusion system $mathcal{F}$. This is then used to obtain a kind of dictionary, which makes it possible to translate between various concepts in localities and corresponding concepts in fusion systems. As a byproduct, we obtain new proofs of many known theorems about fusion systems and also some new results. For example, we show in this paper that, in any saturated fusion system, there is a sensible notion of a product of normal subsystems.
159 - Ellen Henke 2021
The theory of saturated fusion systems resembles in many parts the theory of finite groups. However, some concepts from finite group theory are difficult to translate to fusion systems. For example, products of normal subsystems with other subsystems are only defined in special cases. In this paper the theory of localities is used to prove the following result: Suppose $mathcal{F}$ is a saturated fusion system over a $p$-group $S$. If $mathcal{E}$ is a normal subsystem of $mathcal{F}$ over $Tleq S$, and $mathcal{D}$ is a normal subsystem of $N_{mathcal{F}}(T)$ over $Rleq S$, then there is a normal subsystem $mathcal{E}mathcal{D}$ of $mathcal{F}$ over $TR$, which plays the role of a product of $mathcal{E}$ and $mathcal{D}$ in $mathcal{F}$. It is shown along the way that the subsystem $mathcal{E}mathcal{D}$ is closely related to a naturally arising product in certain localities attached to $mathcal{F}$.
175 - Ellen Henke 2021
Suppose $mathcal{E}$ is a normal subsystem of a saturated fusion system $mathcal{F}$ over $S$. If $Xleq S$ is fully $mathcal{F}$-normalized, then Aschbacher defined a normal subsystem $N_{mathcal{E}}(X)$ of $N_{mathcal{F}}(X)$. In this short note we revisit and generalize this result using the theory of localities. Our more general approach leads in particular to a normal subsystem $C_{mathcal{E}}(X)$ of $C_{mathcal{F}}(X)$ for every $Xleq S$ which is fully $mathcal{F}$-centralized.
214 - Ellen Henke , Jun Liao 2016
We prove that an isomorphism between saturated fusion systems over the same finite p-group is detected on the elementary abelian subgroups of the hyperfocal subgroup if p is odd, and on the abelian subgroups of the hyperfocal subgroup of exponent at most 4 if p = 2. For odd p, this has implications for mod p group cohomology.
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