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mathusers
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Hey there, i have a question on the center of a group, regarding group theory.
QUESTION:
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The centre Z(G) of a group G is defined by Z(G) = g \epsilon G: \forall x \epsilon G, xg = gx
(i) Show that Z(G) is normal subgroup of G
(ii) By considering the Class Equation of G acting on itself by conjugation show that if |G| = p^n ( p prime) then Z(G) \neq {1}
(iii) If G is non abelian show that G/Z(G) is not cyclic.
(iv) Decude that any group of order p^2 is abelian.
(V) Deduce that a gorup of oder p^2 is isomorhpic either to C_{p^2} or to C_p \times C_p
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WHAT I HAVE SO FAR: PLEASE VERIFY THEM
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(i) is not too hard: we let x\in \text{Z}(G) and so we prove that gxg^{-1} \in \text{Z}(G) for any g\in G.
(ii) G \equiv |Z(G)| (mod p) since Z(G) is a fixed point set.
Now |Z(G)| \equiv p^n(mod p), |Z(G)|=0.
So Z(G) has atleast p elements.
(v) We let |G|=p^2. We choose a\not = 1. We form a subgroup H=\left< a \right> if H = G. This implies that the group is cyclic and so the proof is complete. If this is not the case then we pick b\in G\setminus H and form K=\left< b\right>. This means H\cap K = \{ 1\} which further implies HK = G. Also, since the group is abelian H,K\triangleleft G. So G\simeq H\times K \simeq \mathbb{Z}_p \times \mathbb{Z}_p.
please verify these and help me out with the rest. very many thanks :)
QUESTION:
--------------------------------------
The centre Z(G) of a group G is defined by Z(G) = g \epsilon G: \forall x \epsilon G, xg = gx
(i) Show that Z(G) is normal subgroup of G
(ii) By considering the Class Equation of G acting on itself by conjugation show that if |G| = p^n ( p prime) then Z(G) \neq {1}
(iii) If G is non abelian show that G/Z(G) is not cyclic.
(iv) Decude that any group of order p^2 is abelian.
(V) Deduce that a gorup of oder p^2 is isomorhpic either to C_{p^2} or to C_p \times C_p
--------------------------------------
WHAT I HAVE SO FAR: PLEASE VERIFY THEM
--------------------------------------
(i) is not too hard: we let x\in \text{Z}(G) and so we prove that gxg^{-1} \in \text{Z}(G) for any g\in G.
(ii) G \equiv |Z(G)| (mod p) since Z(G) is a fixed point set.
Now |Z(G)| \equiv p^n(mod p), |Z(G)|=0.
So Z(G) has atleast p elements.
(v) We let |G|=p^2. We choose a\not = 1. We form a subgroup H=\left< a \right> if H = G. This implies that the group is cyclic and so the proof is complete. If this is not the case then we pick b\in G\setminus H and form K=\left< b\right>. This means H\cap K = \{ 1\} which further implies HK = G. Also, since the group is abelian H,K\triangleleft G. So G\simeq H\times K \simeq \mathbb{Z}_p \times \mathbb{Z}_p.
please verify these and help me out with the rest. very many thanks :)
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