(Modern Algebra) If G is a finite group with only two classes of conjugation then the...

(Modern Algebra) Show that every finite subgroup of the multiplicative group of a field is cyclical....

(Modern Algebra) Show that every finite subgroup of the multiplicative group of a field is cyclical. (Hint: consider m as the order of the finite subgroup and analyze the roots of the polynomial (x ^ m) - 1 in field F)

(Modern Algebra) Prove using the Lagrange theorem that, except for isomorphisms, there are only two groups...

(Modern Algebra) Prove using the Lagrange theorem that, except for isomorphisms, there are only two groups of order 4 (the cyclic and the Klein group).

Textbook: Algebra A Graduate Course - Isaacs Prove that the group G has exactly two subgroups...

Textbook: Algebra A Graduate Course - Isaacs Prove that the group G has exactly two subgroups iff |G| is prime (and hence finite).

Abstract Algebra (Modern Algebra) Prove that every subgroup of an abelian group is abelian.

Abstract Algebra (Modern Algebra) Prove that every subgroup of an abelian group is abelian.

Let G be a finite group and let H be a subgroup of order n. Suppose...

Let G be a finite group and let H be a subgroup of order n. Suppose that H is the only subgroup of order n. Show that H is normal in G. Hint: Consider the subgroup aHa-1 of G. Please explain in detail!

Let G be a non-trivial finite group, and let H < G be a proper subgroup....

Let G be a non-trivial finite group, and let H < G be a proper subgroup. Let X be the set of conjugates of H, that is, X = {aHa^(−1) : a ∈ G}. Let G act on X by conjugation, i.e., g · (aHa^(−1) ) = (ga)H(ga)^(−1) . Prove that this action of G on X is transitive. Use the previous result to prove that G is not covered by the conjugates of H, i.e., G does not equal...

Let G be a finite group and H be a subgroup of G. Prove that if...

Let G be a finite group and H be a subgroup of G. Prove that if H is only subgroup of G of size |H|, then H is normal in G.

Prove that if (G, ·) is a finite group of even order, then there always exists...

Prove that if (G, ·) is a finite group of even order, then there always exists an element g∈G such that g ≠ 1 and g2=1.

(A) Show that if a2=e for all elements a in a group G, then G must...

(A) Show that if a2=e for all elements a in a group G, then G must be abelian. (B) Show that if G is a finite group of even order, then there is an a∈G such that a is not the identity and a2=e. (C) Find all the subgroups of Z3×Z3. Use this information to show that Z3×Z3 is not the same group as Z9. (Abstract Algebra)

4. Let f : G→H be a group homomorphism. Suppose a∈G is an element of finite...

4. Let f : G→H be a group homomorphism. Suppose a∈G is an element of finite order n. (a) Prove that f(a) has finite order k, where k is a divisor of n. (b) If f is an isomorphism, prove that k=n.