Subquotient Explained

In the mathematical fields of category theory and abstract algebra, a subquotient is a quotient object of a subobject. Subquotients are particularly important in abelian categories, and in group theory, where they are also known as sections, though this conflicts with a different meaning in category theory.

So in the algebraic structure of groups,

is a subquotient of

if there exists a subgroup

and a normal subgroup

G''

so that

is isomorphic to

G'/G''

In the literature about sporadic groups wordings like „

is involved in

“ can be found with the apparent meaning of „

is a subquotient of

“.

As in the context of subgroups, in the context of subquotients the term trivial may be used for the two subquotients

and

\{1\}

which are present in every group

A quotient of a subrepresentation of a representation (of, say, a group) might be called a subquotient representation; e. g., Harish-Chandra's subquotient theorem.^[1]

Example

There are subquotients of groups which are neither subgroup nor quotient of it. E. g. according to article Sporadic group, Fi₂₂ has a double cover which is a subgroup of Fi₂₃, so it is a subquotient of Fi₂₃ without being a subgroup or quotient of it.

Order relation

The relation subquotient of is an order relation – which shall be denoted by

\preceq

. It shall be proved for groups.

Notation

, subgroup

(\Leftrightarrow:G'\leqG)

and normal subgroup

G''

(\Leftrightarrow:G''\vartriangleleftG')

the quotient group

H:=G'/G''

is a subquotient of

, i. e.

H\preceqG

Reflexivity:

G\preceqG

, i. e. every element is related to itself. Indeed,

is isomorphic to the subquotient

G/\{1\}

Antisymmetry: if

G\preceqH

and

H\preceqG

then

G\congH

, i. e. no two distinct elements precede each other. Indeed, a comparison of the group orders of

and

then yields

|G|=|H|

from which

G\congH

Transitivity: if

H'/H''\preceqH

and

H\preceqG

then

H'/H''\preceqG

Proof of transitivity for groups

Let

H'/H''

be subquotient of

, furthermore

H:=G'/G''

be subquotient of

and

\varphi\colonG'\toH

be the canonical homomorphism. Then all vertical (

\downarrow

) maps

\varphi\colonX\toY, x\mapstoxG''

	G''	\leq	\varphi^-1(H'')	\leq	\varphi^-1(H')	\vartriangleleft	G'
\varphi\		\downarrow		\downarrow		\downarrow		\downarrow
	\{1\}	\leq	H''	\vartriangleleft	H'	\vartriangleleft	H

are surjective for the respective pairs

(X,Y) \in

l\{l(G'',\{1\}r)r.

||style="width:8.8em;"|

l(\varphi^-1(H''),H''r)

|| style="width:9.2em;"|

l(\varphi^-1(H'),H'r)

|| style="width:8em;"|

l.l(G',Hr)r\}.

The preimages

\varphi^-1\left(H'\right)

and

\varphi^-1\left(H''\right)

are both subgroups of

containing

G'',

and it is

\varphi\left(\varphi^-1\left(H'\right)\right)=H'

and

\varphi\left(\varphi^-1\left(H''\right)\right)=H'',

because every

h\inH

has a preimage

g\inG'

with

\varphi(g)=h.

Moreover, the subgroup

\varphi^-1\left(H''\right)

is normal in

\varphi^-1\left(H'\right).

As a consequence, the subquotient

H'/H''

is a subquotient of

in the form

H'/H''\cong\varphi^-1\left(H'\right)/\varphi^-1\left(H''\right).

Relation to cardinal order

In constructive set theory, where the law of excluded middle does not necessarily hold, one can consider the relation subquotient of as replacing the usual order relation(s) on cardinals. When one has the law of the excluded middle, then a subquotient

is either the empty set or there is an onto function

X\toY

. This order relation is traditionally denoted

\leq^\ast.

If additionally the axiom of choice holds, then

has a one-to-one function to

and this order relation is the usual

\leq

on corresponding cardinals.

References

p. 310

Subquotient Explained

Example

Order relation

Proof of transitivity for groups

Relation to cardinal order

See also

References