Class of groups

A class of groups $\backslash mathfrak\{X\}$ is a collection of groups such that if $G\; \backslash in\; \backslash mathfrak\{X\}$ and $G\backslash cong\; H$ then $H\; \backslash in\; \backslash mathfrak\{X\}$. Groups in the class $\backslash mathfrak\{X\}~$ are referred to as $\backslash mathfrak\{X\}$-groups.

For a set of groups $\backslash mathfrak\{I\}$, we denote by $(\backslash mathfrak\{I\})$ the smallest class of groups containing $\backslash mathfrak\{I\}$. In particular for a group $G$, $(G)$ denotes its isomorphism class.

The most common examples of classes of groups are:

• $\backslash emptyset$: the empty class of groups
• $\backslash mathfrak\{C\}~$: the class of cyclic groups
• $\backslash mathfrak\{A\}~$: the class of abelian groups
• $\backslash mathfrak\{U\}~$: the class of finite supersolvable groups
• $\backslash mathfrak\{N\}~$: the class of nilpotent groups
• $\backslash mathfrak\{S\}~$: the class of finite solvable groups
• $\backslash mathfrak\{I\}~$: the class of finite simple groups
• $\backslash mathfrak\{F\}~$: the class of finite groups
• $\backslash mathfrak\{G\}~$: the class of all groups

Given two classes of groups $\backslash mathfrak\{X\}$ and $\backslash mathfrak\{Y\}$ it is defined the product of classes

:$\backslash mathfrak\{X\}\backslash mathfrak\{Y\}\; =\; (G\; \backslash mid\; G\; \backslash text\{\; has\; a\; normal\; subgroup\; \}\; N\; \backslash in\; \backslash mathfrak\{X\}\; \backslash text\{\; with\; \}\; G/N\; \backslash in\; \backslash mathfrak\{Y\}).$

This construction allows us to recursively define the power of a class by setting

:$\backslash mathfrak\{X\}^0\; =\; (1)$ and $\backslash mathfrak\{X\}^n\; =\; \backslash mathfrak\{X\}^\{n-1\}\backslash mathfrak\{X\}.$

It must be remarked that this binary operation on the class of classes of groups is neither associative nor commutative. For instance, consider the alternating group of degree 4 (and order 12); this group belongs to the class $(\backslash mathfrak\{C\}\backslash mathfrak\{C\})\backslash mathfrak\{C\}$ because it has as a subgroup the group $V\_4$, which belongs to $\backslash mathfrak\{C\}\backslash mathfrak\{C\}$, and furthermore $A\_4/V\_4\backslash cong\; C\_3$, which is in $\backslash mathfrak\{C\}$. However $A\_4$ has no non-trivial normal cyclic subgroup, so $A\_4\backslash not\backslash in\backslash mathfrak\{C\}(\backslash mathfrak\{C\}\backslash mathfrak\{C\})$. Then $\backslash mathfrak\{C\}(\backslash mathfrak\{C\}\backslash mathfrak\{C\})\backslash not=(\backslash mathfrak\{C\}\backslash mathfrak\{C\})\backslash mathfrak\{C\}$.

However it is straightforward from the definition that for any three classes of groups $\backslash mathfrak\{X\}$, $\backslash mathfrak\{Y\}$, and $\backslash mathfrak\{Z\}$,

:$\backslash mathfrak\{X\}(\backslash mathfrak\{Y\}\backslash mathfrak\{Z\})\backslash subseteq(\backslash mathfrak\{X\}\backslash mathfrak\{Y\})\backslash mathfrak\{Z\}$

A class map c is a map which assigns a class of groups $\backslash mathfrak\{X\}$ to another class of groups $c\backslash mathfrak\{X\}$. A class map is said to be a closure operation if it satisfies the next properties:

1. c is expansive: $\backslash mathfrak\{X\}\backslash subseteq\; c\backslash mathfrak\{X\}$
2. c is idempotent: $c\backslash mathfrak\{X\}=c(c\backslash mathfrak\{X\})$
3. c is monotonic: If $\backslash mathfrak\{X\}\backslash subseteq\backslash mathfrak\{Y\}$ then $c\backslash mathfrak\{X\}\backslash subseteq\; c\backslash mathfrak\{Y\}$

Some of the most common examples of closure operations are:

• $S\backslash mathfrak\{X\}\; =\; (G\; \backslash mid\; G\backslash leq\; H,\; \backslash \; H\backslash in\backslash mathfrak\{X\})$
• $Q\backslash mathfrak\{X\}\; =\; (G\; \backslash mid\; \backslash text\{exists\; \}H\backslash in\backslash mathfrak\{X\}\; \backslash text\{\; and\; an\; epimorphism\; from\; \}\; H\; \backslash text\{\; to\; \}\; G)$
• $N\_0\backslash mathfrak\{X\}\; =\; (G\; \backslash mid\; \backslash text\{\; exists\; \}K\_i\backslash \; (i=1,\backslash cdots,r)\backslash text\{\; subnormal\; in\; \}G\backslash text\{\; with\; \}K\_i\; \backslash in\; \backslash mathfrak\{X\}\backslash text\{\; and\; \}G\; =\; \backslash langle\; K\_1,\backslash cdots,K\_r\backslash rangle)$
• $R\_0\backslash mathfrak\{X\}\; =\; (G\; \backslash mid\; \backslash text\{\; exists\; \}N\_i\backslash \; (i=1,\backslash cdots,r)\backslash text\{\; normal\; in\; \}G\backslash text\{\; with\; \}G/N\_i\; \backslash in\; \backslash mathfrak\{X\}\backslash text\{\; and\; \}\backslash bigcap\backslash limits\_\{i=1\}^rNi=1)$
• $S\_n\backslash mathfrak\{X\}\; =\; (G\; \backslash mid\; G\backslash text\{\; is\; subnormal\; in\; \}\; H\; \backslash text\{\; for\; some\; \}\; H\; \backslash in\; \backslash mathfrak\{X\})$

• Formation

{{reflist}}

• {{Citation | last1=Ballester-Bolinches | first1=Adolfo | last2=Ezquerro | first2=Luis M. | title=Classes of finite groups | url=https://books.google.com/books?id=VoQ53SosWLIC | publisher=Springer-Verlag | location=Berlin, New York | series=Mathematics and Its Applications (Springer) | isbn=978-1-4020-4718-3 | mr=2241927 | year=2006 | volume=584}}
• {{Citation | last1=Doerk | first1=Klaus | last2=Hawkes | first2=Trevor | title=Finite soluble groups | url=https://books.google.com/books?id=E7iL1eWB1TkC | publisher=Walter de Gruyter & Co. | location=Berlin | series=de Gruyter Expositions in Mathematics | isbn=978-3-11-012892-5 | mr=1169099 | year=1992 | volume=4}}

Category:Properties of groups

Category:Group theory

Category:Algebraic structures