Find the number of group homomorphism Z_150 to (Z_200 × D_8)

Find the group homomorphism from Z_14 to A_4, where A4 is the alternating subgroup of S4....

Find the group homomorphism from Z_14 to A_4, where A4 is the alternating subgroup of S4. List the elements of A_4

Let G be a cyclic group, and H be any group. (i) Prove that any homomorphism...

Let G be a cyclic group, and H be any group. (i) Prove that any homomorphism ϕ : G → H is uniquely determined by where it maps a generator of G. In other words, if G = <x> and h ∈ H, then there is at most one homomorphism ϕ : G → H such that ϕ(x) = h. (ii) Why is there ‘at most one’? Give an example where no such homomorphism can exist.

Let φ : A → B be a group homomorphism. Prove that ker φ is a...

Let φ : A → B be a group homomorphism. Prove that ker φ is a normal subgroup of A.

Let G be a group and α : G → H be a homomorphism of groups...

Let G be a group and α : G → H be a homomorphism of groups with H abelian. Show that α factors via G/[G, G], i.e. there exists a homomorphism β : G/[G, G] −→ H, such that α = β◦q, where q : G −→ G/[G, G] is the quotient homomorphis

Can you have a homomorphism from S3 to the group G' with 35 element?

Can you have a homomorphism from S3 to the group G' with 35 element?

Let phi: G1 -> G2 be a surjective group homomorphism. Let H1 be a normal subgroup...

Let phi: G1 -> G2 be a surjective group homomorphism. Let H1 be a normal subgroup of G1 and suppose that phi(H1) = H2. Disprove that G1/H1 G2/H2. Hint: find a counterexample where phi is not injective.

Suppose G, H be groups and φ : G → H be a group homomorphism. Then...

Suppose G, H be groups and φ : G → H be a group homomorphism. Then the for any subgroup K of G, the image φ (K) = {y ∈ H | y = f(x) for some x ∈ G} is a group a group in H.

Letφ:G→G′is a group homomorphism. Prove that φ is one-to-one if and only if Ker(φ) ={e}.

Letφ:G→G′is a group homomorphism. Prove that φ is one-to-one if and only if Ker(φ) ={e}.

Let G be a group and let p be a prime number such that pg =...

Let G be a group and let p be a prime number such that pg = 0 for every element g ∈ G. a.      If G is commutative under multiplication, show that the mapping f : G → G f(x) = xp is a homomorphism b.     If G is an Abelian group under addition, show that the mapping f : G → G f(x) = xpis a homomorphism.

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.