Subject : MATHEMATICS

Paper 1 : ABSTRACT ALGEBRA

Chapter 4 : Nilpotent and solvable groups

Module 1 : Nilpotent groups

Anjan Kumar Bhuniya Department of Mathematics Visva-Bharati; Santiniketan West Bengal

1 Nilpotent groups

Learning Outcomes: 1. Nilpotent groups. 2. Product of two nilpotent groups is nilpotent. 3. Converse of the Lagrange’s Theorem holds on nilpotent groups.

Converse of the Lagrange’s Theorem holds on commutative groups. In this module we charac- terize a more general class of groups, namely nilpotent groups where the converse of the Lagrange’s Theorem holds. Also every nilpotent group is a direct product of its Sylow subgroups and conversely.

Deﬁnition 0.1. (i) Let G be a group. Denote

Z0(G) = {e},

Z1(G) = Z(G),

and Zi+1(G) is the unique normal subgroup of G such that Zi(G) ⊆ Zi+1(G)

and Zi+1(G)/Zi(G) = Z(G/Zi(G)).

Then the chain of normal subgroups

{e} ⊆ Z1(G) ⊆ Z2(G) ⊆ · · ·

is called the upper central series or ascending central series of G.

(ii) A group G is deﬁned to be nilpotent if Zn(G) = G for some n ∈ N.

Example 0.2. Every abelian group G is a nilpotent group, since Z1(G) = Z(G) = G.

But the converse is not true, which we show in the following result.

Theorem 0.3. Every ﬁnite p-group is nilpotent.

Proof. Let G be a ﬁnite p-group. If |G| = 1, then G is nilpotent. Suppose that |G| > 1. Then G being a nontrivial p-group, it follows that Z1(G) = Z(G) 6= {e}. If Z1(G) 6= G, then G/Z1(G) is a nontrivial p-group and |Z(G/Z1(G))| > 1. This implies Z2(G) contains Z1(G) properly, that is Z1(G) ( Z2(G). If Z2(G) 6= G, then similarly Z2(G) ( Z3(G). If for all n ∈ N, Zn(G) 6= G, then we get an inﬁnite strictly ascending chain of subgroups

{e} ( Z1(G) ⊆ Z2(G) ( ···

2 But this can not be , since G is a ﬁnite group. Thus there is n ∈ Z such that Zn(G) = G and G is nilpotent.

Now we an example of a subgroup which is not nilpotent.

Example 0.4. We know that Z(S3) = {e}. Thus Z1(S3) = {e} and S3/Z1(S3) ' S3. This implies

Z(S3/Z1(S3)) = {{e}}. Since Z2(S3) is the unique normal subgroup of S3 such that Z2(S3)/Z1(S3) = Z(S3/Z1(S3)) = {{e}}, so it follows that Z2(S3) = {e}. Similarly, Zn(S3) = {e} for all n ∈ N. Hence S3 is not nilpotent.

Theorem 0.5. The direct product of a ﬁnite number of nilpotent groups is nilpotent.

Proof. This is suﬃcient to prove the result for the direct product of two groups. Let H and K be two nilpotent groups and denote G = H × K.

First we prove that Zn(G) = Zn(H) × Zn(K) for all n ∈ N by the induction on n. We have already proved in the Module 1 on the external direct product of groups that the result holds for n = 1. Assume that Zn(G) = Zn(H) × Zn(K) for some n ≥ 1. Since Zn(H × K) = Zn(H) × Zn(K), so there is an isomorphism ψ : H/Z (H) × K/Z (K) −→ H×K . n n Zn(H×K) Now we have,

Z(G/Zn(G)) =Z(H × K/Zn(H × K))

=Z(ψ(H/Zn(H) × K/Zn(K)))

=ψ(Z(H/Zn(H) × K/Zn(K)))

=ψ(Z(H/Zn(H)) × Z(K/Zn(K)))

=ψ(Zn+1(H)/Zn(H) × Zn+1(K)/Zn(K))

=Zn+1(H) × Zn+1(K)/Zn(H) × Zn(K)

=Zn+1(H) × Zn+1(K)/Zn(H × K)

Since Zn+1(G) is the unique normal subgroup of G such that Zn+1(G)/Zn(G) = Z(G/Zn(G)), so it follows that

Zn+1(G) = Zn+1(H) × Zn+1(K).

Thus, by the principle of mathematical induction, Zn(G) = Zn(H) × Zn(K) for all n = 0, 1, 2, ··· .

Since both H and K are nilpotent, there exists a positive integer n such that Zn(H) = H and

Zn(K) = K. Hence

Zn(H × K) = Zn(H) × Zn(K) = H × K. and H × K is nilpotent.

3 Now we give an alternative equivalent characterization of nilpotent groups, namely by descending central series. Let G be a group and H,K be two subgroups of G. Denote by [H,K] the subgroup generated by all elements of the form hkh−1k−1 for all h ∈ H and k ∈ K. Then we have

Lemma 0.6. Let G be a group, H, K be two subgroups of G and K normal in G. Then [H,G] ⊆ K if and only if HK/K ⊆ Z(G/K).

Deﬁnition 0.7. Let G be a group. Deﬁne inductively

G[1] = G, G[i+1] = [G[i],G] for all i ≥ 1.

Then the chain of normal subgroups

G = G[1] ⊇ G[2] ⊇ · · · is called the descending central series of G.

Theorem 0.8. Let G be a group. Then G is nilpotent if and only if G[n+1] = {e} for some integer n ≥ 0.

Proof. First assume that there is an integer n ≥ 0 such that G[n+1] = {e}. Consider the series

{e} = G[n+1] ⊆ G[n] ⊆ · · · ⊆ G[1] = G.

[i] [i+1] [i+1] [n+1−i] It is easy to check that G /G ⊆ Z(G/G ) for all i = 1, 2, ··· , n and G ⊆ Zi(G) for all [1] i = 0, 1, ··· , n. Thus G = G ⊆ Zn(G), and so G is nilpotent.

Conversely, suppose that G is nilpotent. Then there is an integer n ≥ 1 such that Zn(G) = G. Thus we have a series of normal subgroups

{e} = Z0(G) ⊆ Z1(G) ⊆ · · · ⊆ Zn(G) = G.

[i] [n+1] Then it follows that G ⊆ Zn+1−i(G) for all i = 1, 2, ··· , n + 1. Thus G ⊆ Z0(G) = {e}, and so G[n+1] = {e}.

Theorem 0.9. Every subgroup of a nilpotent group is nilpotent.

Proof. Let G be a group and H be a subgroup of G. Since G is nilpotent, so there is an integer n ≥ 0 such that G[n+1] = {e}. Now we show that H[i] ⊆ G[i] by the induction on i. Now H[1] = H ⊆ G = G[1]. Assume that H[i] ⊆ G[i]. Then H[i+1] = [H[i],H] ⊆ [G[i],G] ⊆ G[i+1] and hence, by the principle of mathematical induction, H[i] ⊆ G[i] for all i = 1, 2, ··· , n + 1. Hence H[n+1] ⊆ G[n+1] = {e}, and so H is nilpotent.

4 Example 0.10. Let G = S3 × Z. Since S3 is not nilpotent, so G is not nilpotent. Thus G is an inﬁnite group which is not nilpotent. Theorem 0.11. A ﬁnite group G is nilpotent if and only if it is the direct product of its Sylow subgroups. Proof. Let G be a nilpotent group. First we show that every Sylow subgroup of G is normal. If possible, let P be a Sylow subgroup of G such that N(P ) 6= G. Denote H = N(P ). Since G is nilpotent, there is n ∈ N such that

{e} = Z0(G) ⊆ Z1(G) ⊆ · · · ⊆ Zn(G) = G

Since H is proper and Z0(G) ⊆ H, so there is the largest index m < n such that Zm(G) ⊆ H. Then Zm+1(G) ( H. Consider a ∈ Zm+1(G) \ H, then Zm+1(G)/Zm(G) implies that aZm(G) ∈ −1 −1 Z(G/Zm(G)) and so haZm(G) = ahZm(G) for every h ∈ H. Hence h a ha ∈ Zm(G) ⊆ H, which implies that a−1ha = h(h−1a−1ha) ∈ H. Thus a−1Ha ⊆ H and a ∈ N(H). Therefore H ( N(H), that is N(P ) ( N(N(P )), which contradicts that P is a Sylow subgroup. Thus N(P ) = G and every Sylow subgroup of G is normal. Hence, G is a direct product of its Sylow subgroups.

Conversely, let G be a direct product of its Sylow subgroups P1,P2, ··· ,Pk. Since Pi is a pi-group for some prime pi, so Pi is nilpotent for every i = 1, 2, ··· , k. Hence their direct product G is also nilpotent.

Now we have the following consequence that shows that the converse of the Lagrange’s Theorem holds on every nilpotent group. Corollary 0.12. Let G be a ﬁnite nilpotent group. Then for every positive divisor m of |G|, G has a subgroup of order m.

n1 n1 nk Proof. Let |G| = p1 p2 ··· pk . Since G is nilpotent, so G = P1 ×P2 ×· · ·×Pk, where Pi is the Sylow ki pi-subgroup of G for i = 1, 2, ··· , k. Also |Pi| = pi . Let m be a positive integer such that m | |G|. m1 m2 mk ni Then m = p1 p2 ··· pk , where 0 ≤ mi ≤ ni. Since Pi is pi-group of order pi and mi ≤ ni, so Pi mi has a subgroup Hi of order pi , by the Sylow’s ﬁrst theorem. Then H = H1 × H2 × · · · × Hk is a m1 m2 mk subgroup of G of order |H1||H2| · · · |Hk| = p1 p2 ··· pk = m.

1 Summary

• (i) Let G be a group. Denote

Z0(G) = {e},

Z1(G) = Z(G),

and Zi+1(G) is the unique normal subgroup of G such that Zi(G) ⊆ Zi+1(G)

and Zi+1(G)/Zi(G) = Z(G/Zi(G)).

5 Then the chain of normal subgroups

{e} ⊆ Z1(G) ⊆ Z2(G) ⊆ · · · is called the upper central series or ascending central series of G.

(ii) A group G is deﬁned to be nilpotent if Zn(G) = G for some n ∈ N.

• Every abelian group G is a nilpotent group, since Z1(G) = Z(G) = G.

• Every ﬁnite p-group is nilpotent.

• The direct product of a ﬁnite number of nilpotent groups is nilpotent.

• Let G be a group and H,K be two subgroups of G. Then [H,K] denotes the subgroup generated by all elements of the form hkh−1k−1 for all h ∈ H and k ∈ K.

• Let G be a group, H, K be two subgroups of G and K normal in G. Then [H,G] ⊆ K if and only if HK/K ⊆ Z(G/K).

• Let G be a group. Deﬁne inductively

G[1] = G, G[i+1] = [G[i],G] for all i ≥ 1.

Then the chain of normal subgroups

G = G[1] ⊇ G[2] ⊇ · · ·

is called the descending central series of G.

• Let G be a group. Then G is nilpotent if and only if G[n+1] = {e} for some integer n ≥ 0.

• Every subgroup of a nilpotent group is nilpotent.

• A ﬁnite group G is nilpotent if and only if it is the direct product of its Sylow subgroups.

• Let G be a ﬁnite nilpotent group. Then for every positive divisor m of |G|, G has a subgroup of order m.