Full invariance does not satisfy image condition: Difference between revisions

Revision as of 13:31, 30 September 2008

This article gives the statement, and possibly proof, of a subgroup property (i.e., fully characteristic subgroup) not satisfying a subgroup metaproperty (i.e., image condition).
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Statement

Suppose $G$ is a group, $K$ is a fully characteristic subgroup of $G$ , and $\varphi :G\to H$ is a surjective homomorphism. Then, $\varphi (K)$ need not be fully characteristic in $H$ .

Proof

Example of a non-Abelian group of prime-cubed order

Further information: Prime-cube order group:p2byp

Suppose $A$ is a cyclic group of order $p^{2}$ and $B$ is a cyclic group of order $p$ , with $B$ acting on $A$ via multiplication by $p+1$ . Then, the semidirect product of $A$ by $B$ is a non-Abelian group of order $p^{3}$ . Call this group $P$ . Define $\Omega _{1}(P)$ (see omega subgroups of a group of prime power order) as the subgroup generated by all elements of order $p$ in $P$ . By the fact that Omega-1 of odd-order class two p-group has prime exponent, $\Omega _{1}(P)$ is a subgroup of prime exponent. This forces it to be a subgroup of order $p^{2}$ generated by the elements of $B$ and the multiples of $p$ in $A$ . All the omega subgroups are fully characteristic, so $\Omega _{1}(P)$ is fully characteristic.

The center of $P$ , namely $Z(P)$ , simply comprises the multiples of $p$ in $A$ . Thus, in the quotient map $P\to P/Z(P)$ , the image of $\Omega _{1}(P)$ is cyclic of order $p$ , while the whole group is elementary Abelian of order $p^{2}$ . Thus:

$\Omega _{1}(P)$ is fully characteristic in $P$ .
The image of $\Omega _{1}(P)$ in $P/Z(P)$ is not fully characteristic in $P/Z(P)$ .

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 {{further|[[Particular example::Prime-cube order group:p2byp]]}}
-Suppose <math>A</math> is a cyclic group of order <math>p^2</math> and <math>B</math> is a cyclic group of order <math>p</math>, with <math>B</math> acting on <math>A</math> via multiplication by <math>p+1</math>. Then, the semidirect product of <math>A</math> by <math>B</math> is a non-Abelian group of order <math>p^3</math>. Call this group <math>P</math>. Define <math>\Omega_1(P)</math> (see [[omega subgroups of a group of prime power order]]) as the subgroup generated by all elements of order <math>p</math> in <math>P</math>. By the fact that [[Omega-1 of odd-order p-group has prime exponent]], <math>\Omega_1(P)</math> is a subgroup of prime exponent. This forces it to be a subgroup of order <math>p^2</math> generated by the elements of <math>B</math> and the multiples of <math>p</math> in <math>A</math>. All the omega subgroups are fully characteristic, so <math>\Omega_1(P)</math> is fully characteristic.
+Suppose <math>A</math> is a cyclic group of order <math>p^2</math> and <math>B</math> is a cyclic group of order <math>p</math>, with <math>B</math> acting on <math>A</math> via multiplication by <math>p+1</math>. Then, the semidirect product of <math>A</math> by <math>B</math> is a non-Abelian group of order <math>p^3</math>. Call this group <math>P</math>. Define <math>\Omega_1(P)</math> (see [[omega subgroups of a group of prime power order]]) as the subgroup generated by all elements of order <math>p</math> in <math>P</math>. By the fact that [[Omega-1 of odd-order class two p-group has prime exponent]], <math>\Omega_1(P)</math> is a subgroup of prime exponent. This forces it to be a subgroup of order <math>p^2</math> generated by the elements of <math>B</math> and the multiples of <math>p</math> in <math>A</math>. All the omega subgroups are fully characteristic, so <math>\Omega_1(P)</math> is fully characteristic.
 The center of <math>P</math>, namely <math>Z(P)</math>, simply comprises the multiples of <math>p</math> in <math>A</math>. Thus, in the quotient map <math>P \to P/Z(P)</math>, the image of <math>\Omega_1(P)</math> is cyclic of order <math>p</math>, while the whole group is elementary Abelian of order <math>p^2</math>. Thus: